Bitumen reflectanceConversion (liquefaction and gasification)Coal chemistrySolid hydrocarbonsCoalbed methaneMacerals in reflected white lightCombustionCombustionCO2 sequestrationCoalbed methaneCoalbed methaneCoalbed methaneCombustionCoalbed methaneCoalbed methaneCoalbed methaneCoal geologyCarbonizationConversion (liquefaction and gasification)Coalbed methaneCoal chemistryCoalbed methaneCoal as oil source rockWeathering and oxidationSolid hydrocarbonsCoal as oil source rockRock-Eval pyrolysisCombustionRock-Eval pyrolysisCoalbed methaneConversion (liquefaction and gasification)Coalbed methaneCoalbed methaneCoal geologyCoalbed-methane associated waterCoal chemistryQuantitative fluorescenceMacerals in reflected white lightMinerals in coalOil shaleCoalbed methane

CarbonizationVisual kerogen analysisVisual kerogen analysisVisual kerogen analysisVisual kerogen analysisVisual kerogen analysisCoal geologyGeneral references Visual kerogen analysisCoal geologyVisual kerogen analysisQuantitative fluorescenceCombustionOil shaleCoal as oil source rockCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoal chemistrySolid hydrocarbonsCoal chemistryConversion (liquefaction and gasification)Coalbed methaneCoalbed methaneCO2 sequestrationCO2 sequestrationCoalbed methaneCO2 sequestrationOil shaleSolid hydrocarbonsSolid hydrocarbonsCoalbed-methane associated waterVitrinite relectance analysisVitrinite reflectanceVitrinite relectance analysisCoal geologyCoal geologyVitrinite reflectanceVisual kerogen analysisSolid hydrocarbons

Coalbed methaneFluorescence microscopyRock-Eval pyrolysisCoalbed methaneMacerals in reflected white lightWeathering and oxidationFluorescence microscopyMacerals in reflected white lightVisual kerogen analysisMacerals in reflected white lightCoal geologyConversion (liquefaction and gasification)Conversion (liquefaction and gasification)Coal ballsOil shaleCoal ballsCoal ballsCoalbed methaneCoal geologyCO2 sequestrationCO2 sequestrationCoalbed methaneCoalbed-methane associated waterCombustionOil shaleCoalbed methaneCoalbed methaneCO2 sequestrationOil shaleOil shaleCoalbed methaneCO2 sequestrationCoalbed-methane associated waterVitrinite reflectanceCoal geologyVitrinite reflectanceCoal chemistryCoal chemistryCoalbed methaneCoal explorationVitrinite reflectance

Vitrinite reflectanceCoalbed methaneCoalbed methaneCoalbed-methane associated waterCoal geologyCoalbed methaneOil shaleCoal explorationCoal chemistryCoalbed-methane associated waterCombustionCoalbed methaneCoal chemistryCombustionWeathering and oxidationWeathering and oxidationCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCO2 sequestrationCoalbed methaneCoalbed methaneCoalbed methaneCO2 sequestrationCO2 sequestrationCO2 sequestrationCoalbed methaneCO2 sequestrationCO2 sequestrationCombustionCoal as oil source rockCoal chemistryCoal chemistryCoalbed methaneCombustionCombustionVisual kerogen analysis

CO2 sequestrationVisual kerogen analysisCoal chemistryCombustionCoalbed methaneCO2 sequestrationCO2 sequestrationConversion (liquefaction and gasification)CO2 sequestrationCombustionCombustionMinerals in coalMinerals in coalRock-Eval pyrolysisCoalbed methaneCoalbed methaneCoal geologyCoal ballsQuantitative fluorescenceCoal geologyCoal geologyKerogen isolationVitrinite reflectanceSuppressed reflectanceVitrinite reflectanceVitrinite reflectanceVitrinite reflectanceVitrinite reflectanceVitrinite relectance analysisVitrinite reflectanceCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneVitrinite reflectanceVitrinite reflectanceVitrinite relectance analysisVitrinite reflectanceVitrinite reflectanceVitrinite reflectanceVitrinite reflectance

Coalbed methaneBitumen reflectanceSolid hydrocarbonsCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneSuppressed reflectanceCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoal as oil source rockVisual kerogen analysisVisual kerogen analysisCO2 sequestrationBitumen reflectanceCoalbed methaneConversion (liquefaction and gasification)Fluorescence microscopyCarbonizationCarbonizationKerogen isolationCoalbed methaneCoal chemistryCoal chemistryKerogen isolationRock-Eval pyrolysisRock-Eval pyrolysisCoalbed methaneVisual kerogen analysisVisual kerogen analysisVisual kerogen analysisVisual kerogen analysisVisual kerogen analysisVisual kerogen analysisVisual kerogen analysisVisual kerogen analysisCoalbed methaneCO2 sequestration

Oil shaleCoal chemistryMinerals in coalCoalbed methaneCoal chemistryCoal ballsVitrinite reflectanceCarbonizationVisual kerogen analysisConversion (liquefaction and gasification)Solid hydrocarbonsWeathering and oxidationCoal chemistryCombustionCombustionCombustionCombustionCoal mine methaneCoalbed methaneCombustionCoalbed methaneCoalbed methaneCoalbed methaneCoal geologyConversion (liquefaction and gasification)Conversion (liquefaction and gasification)Oil shaleCoal geologyCoal geologyMacerals in reflected white lightCoal geologyCoal geologyMacerals in reflected white lightCO2 sequestrationCoal explorationCombustionMacerals in reflected white lightMacerals in reflected white lightCarbonizationMacerals in reflected white lightQuantitative fluorescence

Coal geologyRock-Eval pyrolysisCO2 sequestrationZooclast reflectanceCoal geologyCombustionCoal chemistryMinerals in coalCoalbed methaneCoalbed methaneSolid hydrocarbonsSolid hydrocarbonsCoal geologyMacerals in reflected white lightWeathering and oxidationQuantitative fluorescenceFluorescence microscopyCombustionWeathering and oxidationCombustionCombustionCarbonizationCarbonizationWeathering and oxidationMacerals in reflected white lightCarbonizationCarbonizationChemistry of coal maceralsMacerals in reflected white lightCombustionCombustionConversion (liquefaction and gasification)CO2 sequestrationQuantitative fluorescenceQuantitative fluorescenceVitrinite reflectanceVitrinite reflectanceMacerals in reflected white lightVitrinite reflectanceCO2 sequestrationCoalbed methane

Coal explorationCoalbed methaneCoal chemistryCoal explorationCoal chemistryWeathering and oxidationCoal geologyCombustionCarbonizationCoalbed methaneCO2 sequestrationCoal explorationCoal as oil source rockMacerals in reflected white lightRock-Eval pyrolysisCoal as oil source rockVisual kerogen analysisCoal geologyCoal as oil source rockFluorescence microscopyQuantitative fluorescenceQuantitative fluorescenceSolid hydrocarbonsZooclast reflectanceZooclast reflectanceZooclast reflectanceBitumen reflectanceSolid hydrocarbonsZooclast reflectanceBitumen reflectanceRock-Eval pyrolysisZooclast reflectanceZooclast reflectanceSolid hydrocarbonsZooclast reflectanceZooclast reflectanceKerogen isolationVisual kerogen analysisSolid hydrocarbonsCoal chemistryCombustion

Coalbed methaneCoalbed methaneConversion (liquefaction and gasification)CombustionCoal mine methaneCoalbed methaneCoal mine methaneCoalbed methaneCO2 sequestrationConversion (liquefaction and gasification)Vitrinite reflectanceConversion (liquefaction and gasification)Vitrinite reflectanceOil shaleOil shaleOil shaleOil shaleMinerals in coalMinerals in coalVitrinite reflectanceVisual kerogen analysisGeneral references Weathering and oxidationWeathering and oxidationCoal geologyMacerals in reflected white lightMineral matrix effectsSolid hydrocarbonsSolid hydrocarbonsSolid hydrocarbonsCoal geologyFluorescence microscopyKerogen isolationCoal chemistryCombustionCombustionOil shaleOil shaleOil shaleOil shaleCoalbed methane

Coal chemistryCarbonizationCoalbed methaneSolid hydrocarbonsSolid hydrocarbonsCoal geologyMinerals in coalMacerals in reflected white lightCoal explorationCoal chemistryCoalbed methaneRock-Eval pyrolysisMacerals in reflected white lightCoal as oil source rockCoal as oil source rockCoal as oil source rockCoalbed methaneCoalbed methaneCombustionVitrinite reflectanceCombustionConversion (liquefaction and gasification)Coalbed methaneVitrinite reflectanceVisual kerogen analysisVitrinite relectance analysisSuppressed reflectanceVitrinite reflectanceKerogen isolationGeneral references Vitrinite reflectanceVitrinite reflectanceMineral matrix effectsVitrinite reflectanceCoal chemistryRock-Eval pyrolysisVitrinite reflectanceCoal chemistryCoal as oil source rockVisual kerogen analysisCarbonization

Coal chemistryVisual kerogen analysisCO2 sequestrationCO2 sequestrationWeathering and oxidationCoal ballsCoal chemistryCoalbed methaneCoalbed methaneCoalbed methaneCoalbed-methane associated waterCO2 sequestrationCoal as oil source rockOil shaleCO2 sequestrationCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoal chemistryCoal chemistryFluorescence microscopyCoalbed methaneVisual kerogen analysisSolid hydrocarbonsWeathering and oxidationCombustionCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneOil shaleCO2 sequestrationCO2 sequestrationChemistry of coal maceralsCoalbed-methane associated waterVitrinite reflectanceSolid hydrocarbonsConversion (liquefaction and gasification)CO2 sequestrationVisual kerogen analysis

Visual kerogen analysisCoal as oil source rockCoal as oil source rockCoal as oil source rockCoal as oil source rockCombustionRock-Eval pyrolysisCoalbed methaneKerogen isolationCO2 sequestrationCO2 sequestrationChemistry of coal maceralsMacerals in reflected white lightVitrinite reflectanceCarbonizationQuantitative fluorescenceCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCombustionOil shaleOil shaleCoal chemistryCoal chemistryKerogen isolationMacerals in reflected white lightWeathering and oxidationCoalbed methaneSolid hydrocarbonsCoal mine methaneCoalbed methaneKerogen isolationCoal explorationCO2 sequestrationBitumen reflectanceVitrinite reflectanceZooclast reflectanceSolid hydrocarbonsVitrinite relectance analysisVisual kerogen analysis

CarbonizationCoal chemistryCombustionOil shaleConversion (liquefaction and gasification)Conversion (liquefaction and gasification)Vitrinite reflectanceConversion (liquefaction and gasification)CarbonizationMacerals in reflected white lightZooclast reflectanceMinerals in coalConversion (liquefaction and gasification)Visual kerogen analysisCO2 sequestrationCoal geologyVitrinite reflectanceRock-Eval pyrolysisZooclast reflectanceOil shaleVitrinite reflectanceCoal mine methaneCoal mine methaneFluorescence microscopyCO2 sequestrationConversion (liquefaction and gasification)CO2 sequestrationCoalbed methaneCoalbed methaneCO2 sequestrationSequestration in shalesCO2 sequestrationCoalbed methaneCO2 sequestrationCoalbed methaneCO2 sequestrationCoalbed methaneCoalbed methaneCoal geologyCoalbed methaneCoalbed methane

Chemistry of coal maceralsWeathering and oxidationCoal as oil source rockVisual kerogen analysisMacerals in reflected white lightCoalbed methaneCoalbed methaneCO2 sequestrationCoalbed methaneChemistry of coal maceralsVitrinite relectance analysisGeneral references Coal geologyCoalbed methaneCoalbed methaneMacerals in reflected white lightZooclast reflectanceVitrinite reflectanceCoal chemistryChemistry of coal maceralsCoal chemistryChemistry of coal maceralsChemistry of coal maceralsCO2 sequestrationCoalbed methaneCoalbed methaneCoalbed methaneCoal geologyCoalbed methaneCoalbed methaneCoalbed methaneCO2 sequestrationCoalbed methaneCoal ballsMacerals in reflected white lightMacerals in reflected white lightCoal geologyWeathering and oxidationCoalbed methaneCoalbed methaneCoalbed methane

Coal geologyCoal geologyCoal geologyCoal geologyWeathering and oxidationWeathering and oxidationCoal chemistryCoal as oil source rockMacerals in reflected white lightMacerals in reflected white lightCoal geologyVitrinite reflectanceVitrinite reflectanceCoal chemistryMacerals in reflected white lightCoal geologyMacerals in reflected white lightCoalbed methaneCoalbed methaneCoalbed methaneCoalbed-methane associated waterConversion (liquefaction and gasification)Coal geologyCoalbed methaneCoalbed methaneOil shaleCombustionOil shaleCO2 sequestrationCoal mine methaneCoal mine methaneCoalbed methaneVitrinite reflectanceCombustionCO2 sequestrationSolid hydrocarbonsCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methane

Coalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneOil shaleVitrinite reflectanceCoalbed methaneVitrinite reflectanceVitrinite relectance analysisCoalbed methaneZooclast reflectanceSolid hydrocarbonsBitumen reflectanceSolid hydrocarbonsCoalbed methaneCombustionCombustionCoal chemistryCoal geologyConversion (liquefaction and gasification)CombustionEffects of overpressure on vitrinite reflectanceSuppressed reflectanceVitrinite reflectanceSuppressed reflectanceVitrinite reflectanceSuppressed reflectanceVitrinite reflectanceVitrinite reflectanceVitrinite reflectanceVitrinite relectance analysisCO2 sequestrationCO2 sequestrationCoalbed methaneCombustionCoal geologyRock-Eval pyrolysisOil shaleCoalbed methaneCO2 sequestrationCoalbed methane

CO2 sequestrationCoal geologyCoal explorationCoalbed methaneCoal geologyCoal chemistryCoal geologyCoal chemistryCarbonizationCoal geologyCarbonizationOil shaleVitrinite reflectanceVitrinite relectance analysisVisual kerogen analysisVitrinite reflectanceMacerals in reflected white lightCoalbed methaneCoalbed methaneCoal geologyCoal geologyCoal explorationCoal geologyMinerals in coalCoal explorationMinerals in coalMinerals in coalCoal chemistryCoal geologyCoalbed methaneCO2 sequestrationCoalbed methaneCO2 sequestrationConversion (liquefaction and gasification)Coalbed methaneCO2 sequestrationCoalbed methaneConversion (liquefaction and gasification)Coal geologyCoal geologyCoal chemistry

Conversion (liquefaction and gasification)Coal chemistryCoalbed methaneCoalbed methaneCoal geologyCoal geologyMacerals in reflected white lightCoalbed methaneWeathering and oxidationWeathering and oxidationVitrinite reflectanceWeathering and oxidationCombustionCoalbed methaneWeathering and oxidationWeathering and oxidationQuantitative fluorescenceVitrinite reflectanceCO2 sequestrationCO2 sequestrationSequestration in shalesCO2 sequestrationOil shaleCO2 sequestrationCoalbed methaneCoalbed methaneCO2 sequestrationCoal chemistryFluorescence microscopyCoal chemistryVitrinite reflectanceCoalbed methaneCoalbed methaneCoal chemistryWeathering and oxidationCombustionConversion (liquefaction and gasification)CO2 sequestrationCoalbed methaneCoalbed methaneCoal geology

Coal geologyCoal chemistryCoalbed methaneCoalbed-methane associated waterCoalbed methaneCoalbed-methane associated waterZooclast reflectanceCoalbed methaneCO2 sequestrationOil shaleWeathering and oxidationSolid hydrocarbonsCarbonizationCarbonizationCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoal chemistryCoal chemistryCoal chemistryCoal chemistryCombustionCombustionSolid hydrocarbonsCoal geologyCoal geologyCoalbed methaneCoal geologyWeathering and oxidationCombustionCoal chemistryCoal chemistryCoalbed methaneCoalbed methaneCoal geologyCoalbed methaneCO2 sequestrationOil shale

Oil shaleCoalbed methaneCombustionCoal chemistryCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneMacerals in reflected white lightCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneZooclast reflectanceVisual kerogen analysisCoalbed methaneCoal as oil source rockCoalbed methaneWeathering and oxidationWeathering and oxidationCoal as oil source rockCoal chemistryCombustionWeathering and oxidationWeathering and oxidationConversion (liquefaction and gasification)Weathering and oxidationRock-Eval pyrolysisCombustionQuantitative fluorescenceCoalbed methaneCoal geologyCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methane

Coalbed methaneMinerals in coalCoal explorationCoal geologyCoal chemistryMinerals in coalMinerals in coalCoal chemistryCoal geologyCoal geologyCoal geologyCoal geologyCoal geologyCoal geologyCoal geologyCoal geologyCoal geologyCoal geologyCoal geologyCoal geologyVitrinite reflectanceCoal geologyCoal geologyCoal geologyCoal geologyMacerals in reflected white lightCoal geologyCoal geologyCoal geologyCoal geologyCoal geologyVitrinite reflectanceCoal chemistryCoal geologyCoal geologyCoalbed methaneCoalbed methaneCoalbed methaneCarbonizationVisual kerogen analysisZooclast reflectance

Coal chemistryCoalbed methaneCoal geologyCoal as oil source rockConversion (liquefaction and gasification)Coalbed methaneCoalbed-methane associated waterCarbonizationOil shaleVisual kerogen analysisVisual kerogen analysisVisual kerogen analysisVisual kerogen analysisOil shaleOil shaleCoalbed methaneCoalbed methaneCO2 sequestrationCoalbed methaneCoalbed methaneCO2 sequestrationCoalbed methaneCoalbed methaneOil shaleVisual kerogen analysisOil shaleVisual kerogen analysisVitrinite reflectanceCoal as oil source rockOil shaleVisual kerogen analysisVitrinite reflectanceCoal as oil source rockCoal geologyCoalbed methaneCombustionCoal chemistryMacerals in reflected white lightCoalbed methaneVitrinite reflectanceRock-Eval pyrolysis

Vitrinite reflectanceWeathering and oxidationWeathering and oxidationMacerals in reflected white lightCoal geologyMacerals in reflected white lightMacerals in reflected white lightMacerals in reflected white lightCoal geologyMacerals in reflected white lightCoal explorationSolid hydrocarbonsConversion (liquefaction and gasification)Rock-Eval pyrolysisSuppressed reflectanceCoal geologyWeathering and oxidationVisual kerogen analysisVisual kerogen analysisVisual kerogen analysisVisual kerogen analysisSuppressed reflectanceCombustionCoalbed methaneCoal geologyCoalbed-methane associated waterWeathering and oxidationVisual kerogen analysisCoalbed methaneCoalbed methaneSolid hydrocarbonsSolid hydrocarbonsSolid hydrocarbonsCoal chemistryWeathering and oxidationOil shaleFluorescence microscopyMacerals in reflected white lightVitrinite reflectanceVisual kerogen analysisCarbonization

Coalbed methaneCoalbed methaneMinerals in coalMacerals in reflected white lightVitrinite reflectanceFluorescence microscopyQuantitative fluorescenceMacerals in reflected white lightCarbonizationMacerals in reflected white lightMacerals in reflected white lightCombustionMacerals in reflected white lightMacerals in reflected white lightGeneral references CarbonizationMacerals in reflected white lightFluorescence microscopyQuantitative fluorescenceKerogen isolationMacerals in reflected white lightCombustionMacerals in reflected white lightConversion (liquefaction and gasification)Fluorescence microscopyCombustionMacerals in reflected white lightVitrinite reflectanceCombustionMacerals in reflected white lightCarbonizationWeathering and oxidationMacerals in reflected white lightQuantitative fluorescenceMinerals in coalSolid hydrocarbonsVisual kerogen analysisOil shaleCO2 sequestrationConversion (liquefaction and gasification)Coal geology

Macerals in reflected white lightCoal geologyMacerals in reflected white lightCoal geologyMacerals in reflected white lightCoalbed methaneCoalbed methaneSolid hydrocarbonsCoal geologyCoalbed methaneCombustionMinerals in coalCoal chemistryCombustionConversion (liquefaction and gasification)Coalbed methaneCoalbed methaneCoalbed methaneCoal as oil source rockSolid hydrocarbonsSolid hydrocarbonsSolid hydrocarbonsSolid hydrocarbonsSolid hydrocarbonsCoal as oil source rockSolid hydrocarbonsCoal as oil source rockSolid hydrocarbonsCoalbed methaneCoal as oil source rockCoal as oil source rockCoal chemistryMinerals in coalMacerals in reflected white lightCO2 sequestrationCoalbed methaneMacerals in reflected white lightCoal geologyCoalbed methaneCoalbed methaneCoalbed-methane associated water

Rock-Eval pyrolysisCoalbed methaneCoalbed methaneCoal chemistryMinerals in coalMinerals in coalCoal chemistryCoal chemistryMinerals in coalCoal chemistryMinerals in coalMinerals in coalCombustionCoal chemistryMinerals in coalCoal chemistryCombustionMinerals in coalCombustionMinerals in coalMinerals in coalCoal chemistryCoal chemistryMinerals in coalCoal chemistryMinerals in coalCoal chemistryMinerals in coalCoal chemistryEffects of overpressure on vitrinite reflectanceVitrinite reflectanceCO2 sequestrationCoalbed methaneCoalbed methaneCoalbed-methane associated waterCoal chemistryMacerals in reflected white lightCO2 sequestrationCO2 sequestrationKerogen isolationCoal mine methane

Coalbed methaneCoal chemistryVitrinite reflectanceCoal chemistryMacerals in reflected white lightCoal geologyCoalbed methaneVisual kerogen analysisCoal chemistryCoalbed methaneCoalbed methaneCO2 sequestrationCoalbed methaneVitrinite reflectanceCoal chemistryCoal chemistryWeathering and oxidationWeathering and oxidationCoal chemistryCoal chemistryCombustionCoal chemistryCoal chemistryCoalbed methaneVitrinite reflectanceVisual kerogen analysisCoal geologyMacerals in reflected white lightCoal geologyCarbonizationVitrinite reflectanceVitrinite relectance analysisVitrinite reflectanceVitrinite relectance analysisCoal geologyMacerals in reflected white lightVitrinite reflectanceCarbonizationConversion (liquefaction and gasification)Vitrinite reflectanceFluorescence microscopy

Quantitative fluorescenceMinerals in coalConversion (liquefaction and gasification)Rock-Eval pyrolysisCoal as oil source rockCoal geologyCarbonizationCoalbed methaneCoalbed methaneCoalbed methaneCoal geologyCoalbed methaneCoalbed methaneCoalbed methaneMinerals in coalCoalbed methaneCombustionCO2 sequestrationCO2 sequestrationCoalbed methaneCO2 sequestrationCoalbed methaneCO2 sequestrationCoalbed methaneCoal chemistryCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCO2 sequestrationCO2 sequestrationCO2 sequestrationCoal mine methaneCoal explorationVitrinite reflectanceCoal geologyFluorescence microscopyCoal chemistryCoalbed methane

Coalbed methaneCoal geologyCoal geologyCoalbed methaneCoalbed methaneCoalbed methaneSolid hydrocarbonsRock-Eval pyrolysisRock-Eval pyrolysisCoal ballsCoal geologyRock-Eval pyrolysisRock-Eval pyrolysisVisual kerogen analysisVitrinite reflectanceVitrinite relectance analysisRock-Eval pyrolysisMacerals in reflected white lightCoal geologyCoal chemistryMinerals in coalCoal chemistryCoal chemistryCoalbed methaneCoal chemistryCoal chemistryCoal geologyCoalbed methaneCoalbed methaneCoalbed-methane associated waterCO2 sequestrationCombustionVitrinite reflectanceConversion (liquefaction and gasification)Quantitative fluorescenceCoal chemistryConversion (liquefaction and gasification)Visual kerogen analysisVisual kerogen analysisVisual kerogen analysisCoalbed methane

Coal chemistryCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoal explorationCarbonizationVitrinite reflectanceVitrinite reflectanceRock-Eval pyrolysisSuppressed reflectanceVitrinite reflectanceVitrinite relectance analysisVitrinite reflectanceZooclast reflectanceRock-Eval pyrolysisCoalbed methaneVisual kerogen analysisCoalbed methaneCoalbed methaneCoalbed methaneCoal mine methaneCoalbed methaneCoalbed methaneCoal mine methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCombustionMinerals in coalCoalbed methaneCoal mine methaneMinerals in coalCoal chemistryMinerals in coal

Coal chemistryCoal geologyMacerals in reflected white lightCoal geologyMacerals in reflected white lightCarbonizationQuantitative fluorescenceCoal geologyMacerals in reflected white lightCoal geologyGeneral references Coal geologyMacerals in reflected white lightCombustionCoal geologyCoal geologyMacerals in reflected white lightCarbonizationQuantitative fluorescenceSuppressed reflectanceVitrinite reflectanceMacerals in reflected white lightConversion (liquefaction and gasification)CarbonizationCoal geologyMinerals in coalCoal geologyCoal geologyCoal geologyMacerals in reflected white lightCoal geologyOil shaleCO2 sequestrationMacerals in reflected white lightQuantitative fluorescenceWeathering and oxidationCO2 sequestrationCoalbed methaneKerogen isolationCoal geologyCoal geology

Coal geologyCO2 sequestrationCombustionOil shaleOil shaleCoalbed methaneChemistry of coal maceralsMacerals in reflected white lightCoal chemistryCoalbed methaneSolid hydrocarbonsConversion (liquefaction and gasification)Vitrinite reflectanceVitrinite relectance analysisVitrinite relectance analysisVisual kerogen analysisCoalbed methaneCO2 sequestrationCoal explorationCO2 sequestrationCoalbed methaneCoal chemistryCoalbed methaneVitrinite reflectanceCoal as oil source rockCO2 sequestrationCoal mine methaneCoalbed methaneOil shaleCoalbed methaneMacerals in reflected white lightSolid hydrocarbonsOil shaleOil shaleCombustionWeathering and oxidationVisual kerogen analysisCoalbed methaneKerogen isolationCoal as oil source rockRock-Eval pyrolysis

Mineral matrix effectsVitrinite reflectanceCO2 sequestrationCO2 sequestrationOil shaleCoal geologyCarbonizationCoal explorationChemistry of coal maceralsCoal geologyQuantitative fluorescenceCO2 sequestrationCoalbed methaneCO2 sequestrationCoalbed methaneMacerals in reflected white lightMacerals in reflected white lightCoal as oil source rockCoal geologyCO2 sequestrationOil shaleOil shaleOil shaleOil shaleOil shaleOil shaleOil shaleChemistry of coal maceralsChemistry of coal maceralsCoal chemistrySolid hydrocarbonsCoal geologyCoal explorationCoalbed methaneCoalbed methaneCoal geologyQuantitative fluorescenceCoalbed methaneCoal geologyCoal geologyCoalbed methane

Visual kerogen analysisCoal geologyCoal geologyCoal geologyVisual kerogen analysisCoalbed methaneBitumen reflectanceCoal geologyCoal ballsMacerals in reflected white lightCombustionCoal explorationCO2 sequestrationCO2 sequestrationCoalbed methaneCoalbed methaneCarbonizationConversion (liquefaction and gasification)CombustionCoalbed methaneCoalbed methaneCoalbed methaneCombustionCombustionWeathering and oxidationQuantitative fluorescenceSuppressed reflectanceCoalbed methaneKerogen isolationCombustionCoalbed methaneCoalbed methaneCoalbed methaneGeneral references Coal geologyVitrinite reflectanceCombustionCombustionCoal geologyCO2 sequestrationCO2 sequestration

Coalbed methaneCoal mine methaneCoalbed methaneVitrinite reflectanceVisual kerogen analysisCoal geologyCoalbed methaneCoal explorationOil shaleCoal chemistryCoal chemistryCoal chemistryCoal chemistryCoal chemistryCoal chemistryCoal chemistryCoal chemistryRock-Eval pyrolysisRock-Eval pyrolysisRock-Eval pyrolysisRock-Eval pyrolysisRock-Eval pyrolysisCombustionCO2 sequestrationCoal geologyCoal geologyCoal geologyCoal geologyMacerals in reflected white lightCoalbed methaneCoalbed methaneWeathering and oxidationCoalbed methaneCoal ballsCoal chemistryCombustionConversion (liquefaction and gasification)Macerals in reflected white lightCoal chemistryCombustionCoal chemistry

Coal geologyCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneGeneral references Coal geologyCoal chemistryMinerals in coalCoal geologyCoal geologyCoal geologyCoal ballsCoal explorationCoal geologyCoalbed methaneCoalbed methaneQuantitative fluorescenceCoalbed methaneVitrinite relectance analysisCoalbed methaneMacerals in reflected white lightCoalbed methaneCoal as oil source rockCoal geologyCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCO2 sequestrationCoalbed methaneCoalbed methaneSequestration in shalesOil shaleWeathering and oxidationVitrinite reflectanceVitrinite relectance analysisOil shaleKerogen isolation

Minerals in coalKerogen isolationVisual kerogen analysisCombustionCoalbed methaneCoalbed methaneCoal chemistryCoalbed methaneMacerals in reflected white lightCoal geologyCoal geologyCoal geologyCoal geologyCoal geologyCoal geologySuppressed reflectanceVitrinite reflectanceCombustionCO2 sequestrationCoalbed methaneCoal geologyCoal as oil source rockCoalbed methaneConversion (liquefaction and gasification)Kerogen isolationMinerals in coalCoalbed methaneMinerals in coalCoal chemistryCombustionCoal chemistryCoal chemistryMinerals in coalCoal chemistryCombustionCombustionCoal chemistryCombustionSolid hydrocarbonsCoal chemistryCoal chemistry

Minerals in coalCoal chemistryCombustionCO2 sequestrationSequestration in shalesWeathering and oxidationWeathering and oxidationOil shaleOil shaleConversion (liquefaction and gasification)Coalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneVisual kerogen analysisCoal geologyCoal as oil source rockOil shaleCoal geologyCoal geologyCoal geologyCoalbed methaneCoalbed methaneCoal geologyCoalbed methaneCoalbed methaneGeneral references Coal geologyCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoal geologyCO2 sequestrationCombustionCoalbed methaneCoalbed methaneCarbonizationWeathering and oxidationCO2 sequestrationCoal chemistry

Solid hydrocarbonsSolid hydrocarbonsCoal as oil source rockMacerals in reflected white lightCO2 sequestrationCO2 sequestrationCoal geologyVisual kerogen analysisMinerals in coalWeathering and oxidationCoalbed methaneCombustionCoal geologyMacerals in reflected white lightCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoal geologyCoalbed methaneCoalbed-methane associated waterCoal chemistryMinerals in coalOil shaleOil shaleOil shaleOil shaleOil shaleCoalbed methaneCoalbed methaneCarbonizationCO2 sequestrationCombustionCoal chemistryConversion (liquefaction and gasification)Coalbed methaneCoal chemistryCombustionCoalbed methaneCarbonizationConversion (liquefaction and gasification)

Coal mine methaneCoalbed methaneCO2 sequestrationCoalbed methaneCoal explorationCoal geologyCoal ballsCoal geologyCoalbed methaneCoalbed methaneCoalbed methaneMacerals in reflected white lightCoal chemistryVisual kerogen analysisCoalbed methaneCoal mine methaneCoalbed methaneCoalbed methaneCoal as oil source rockCoal geologyCoal geologyCO2 sequestrationCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoal geologyCoal geologyCoal geologyCoal geologyCoal geologyCoal geologyCoal geologyCoalbed methaneOil shaleCoalbed methaneMinerals in coalCoal geologyCoal chemistryCoal chemistryCoal chemistry

Coal explorationVisual kerogen analysisCoalbed methaneCoalbed methaneCO2 sequestrationCO2 sequestrationCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCombustionCombustionCombustionCombustionCoalbed methaneCombustionBitumen reflectanceSolid hydrocarbonsSuppressed reflectanceVitrinite reflectanceSolid hydrocarbonsSolid hydrocarbonsSuppressed reflectanceVitrinite reflectanceCoalbed methaneMineral matrix effectsRock-Eval pyrolysisVitrinite reflectanceVitrinite relectance analysisWeathering and oxidationCarbonizationConversion (liquefaction and gasification)Coalbed methaneMineral matrix effectsConversion (liquefaction and gasification)Macerals in reflected white lightCoal chemistryConversion (liquefaction and gasification)Coalbed methaneCoalbed methaneCoalbed methane

Coalbed methaneZooclast reflectanceCoalbed methaneVitrinite reflectanceCoal as oil source rockSolid hydrocarbonsSuppressed reflectanceSolid hydrocarbonsQuantitative fluorescenceCoal ballsVitrinite reflectanceCoal chemistryCoalbed methaneChemistry of coal maceralsCO2 sequestrationCombustionCoal geologyCoal geologyCoal geologyCoal chemistryCombustionCoal geologyCoal geologyCoal geologyCarbonizationCoalbed methaneCO2 sequestrationCarbonizationWeathering and oxidationCoalbed methaneCoal chemistryCarbonizationCoal chemistryCoal geologyCoal chemistryMacerals in reflected white lightCoal geologyCoal geologyCoal chemistryCoal chemistryCoal chemistry

Conversion (liquefaction and gasification)Conversion (liquefaction and gasification)Coal chemistryConversion (liquefaction and gasification)Conversion (liquefaction and gasification)Conversion (liquefaction and gasification)Coal chemistryMacerals in reflected white lightCoal geologyCoal geologySolid hydrocarbonsSolid hydrocarbonsCoalbed methaneCoal geologyCoal geologyMacerals in reflected white lightCoal geologyMacerals in reflected white lightCoal geologyCoal geologyCoal chemistryCoal chemistryMinerals in coalSamplingSamplingMacerals in reflected white lightVisual kerogen analysisCoal as oil source rockCoalbed methaneBitumen reflectanceSolid hydrocarbonsRock-Eval pyrolysisVisual kerogen analysisCoal geologyCoal chemistryCoal chemistryCoal chemistryCoal chemistryCoal explorationMinerals in coalCO2 sequestration

Sequestration in shalesCoalbed-methane associated waterMinerals in coalMinerals in coalMinerals in coalMacerals in reflected white lightVitrinite reflectanceCoalbed methaneCoalbed methaneCoal chemistrySamplingConversion (liquefaction and gasification)Coalbed methaneVitrinite reflectanceCarbonizationZooclast reflectanceMacerals in reflected white lightZooclast reflectanceZooclast reflectanceCarbonizationMacerals in reflected white lightMacerals in reflected white lightVitrinite reflectanceSolid hydrocarbonsVisual kerogen analysisZooclast reflectanceWeathering and oxidationVitrinite reflectanceFluorescence microscopyMacerals in reflected white lightZooclast reflectanceCombustionCombustionCombustionCoal chemistryCombustionZooclast reflectanceCarbonizationZooclast reflectanceZooclast reflectanceZooclast reflectance

CarbonizationVitrinite reflectanceVitrinite reflectanceVitrinite reflectanceWeathering and oxidationWeathering and oxidationCarbonizationWeathering and oxidationVitrinite reflectanceCarbonizationVitrinite reflectanceCarbonizationVitrinite reflectanceMacerals in reflected white lightCoal chemistryCombustionCoal chemistryCoal chemistryCoal chemistryMinerals in coalCoal chemistryCoal chemistryCoal chemistryCoal chemistryCombustionCombustionVisual kerogen analysisZooclast reflectanceSolid hydrocarbonsCoal chemistrySolid hydrocarbonsFluorescence microscopySolid hydrocarbonsSolid hydrocarbonsCombustionMacerals in reflected white lightCoal geologyCoal chemistryCoal chemistryCombustionCarbonization

Coal chemistryMinerals in coalCombustionCoal as oil source rockMacerals in reflected white lightSuppressed reflectanceVitrinite reflectanceZooclast reflectanceZooclast reflectanceZooclast reflectanceSolid hydrocarbonsZooclast reflectanceSolid hydrocarbonsCoal geologyCombustionZooclast reflectanceSolid hydrocarbonsSolid hydrocarbonsMineral matrix effectsSuppressed reflectanceVitrinite reflectanceMineral matrix effectsSuppressed reflectanceVitrinite reflectanceCO2 sequestrationCoalbed methaneCO2 sequestrationCO2 sequestrationCarbonizationCarbonizationCoal chemistryCoal chemistryConversion (liquefaction and gasification)Zooclast reflectanceMacerals in reflected white lightCarbonizationCarbonizationCoalbed methaneVitrinite reflectanceMacerals in reflected white lightCoal geology

Coal explorationCoal geologyMacerals in reflected white lightCoal ballsCoal ballsVisual kerogen analysisRock-Eval pyrolysisConversion (liquefaction and gasification)Conversion (liquefaction and gasification)CarbonizationCombustionCoalbed methaneCoalbed methaneConversion (liquefaction and gasification)Conversion (liquefaction and gasification)Coalbed methaneCoalbed methaneKerogen isolationCarbonizationMacerals in reflected white lightCarbonizationCarbonizationCarbonizationWeathering and oxidationCarbonizationWeathering and oxidationCarbonizationCarbonizationCarbonizationCarbonizationCarbonizationVitrinite reflectanceVisual kerogen analysisQuantitative fluorescenceVisual kerogen analysisCoal explorationCoal geologyCoal geologyCoal geologySamplingCoal geology

Coal ballsCoal geologyCoal geologyCoal geologyCoal geologyCoalbed methaneVisual kerogen analysisQuantitative fluorescenceVisual kerogen analysisCoal chemistryCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoal chemistryVitrinite reflectanceCoal chemistryCarbonizationMinerals in coalCarbonizationCarbonizationCO2 sequestrationCoalbed methaneCarbonizationCombustionCoal chemistryCombustionCO2 sequestrationCombustionCoalbed methaneWeathering and oxidationVitrinite reflectanceCombustionCombustionCarbonizationVitrinite reflectanceCoalbed methaneCoalbed methane

Coal geologyCO2 sequestrationCoalbed methaneCO2 sequestrationSolid hydrocarbonsCombustionMacerals in reflected white lightCoal as oil source rockVisual kerogen analysisMacerals in reflected white lightCarbonizationCoal chemistryCO2 sequestrationCO2 sequestrationOil shaleCoalbed methaneMacerals in reflected white lightMacerals in reflected white lightCoal chemistryCoalbed methaneCoalbed methaneCombustionCarbonizationSuppressed reflectanceVitrinite reflectanceChemistry of coal maceralsCoalbed methaneChemistry of coal maceralsSuppressed reflectanceCoalbed methaneCoalbed methaneCoalbed methaneCoal chemistryCoal chemistryCoal geologyCoalbed methaneCoalbed methaneOil shaleVisual kerogen analysisVisual kerogen analysisSampling

CO2 sequestrationVisual kerogen analysisMacerals in reflected white lightCoal geologySuppressed reflectanceVitrinite reflectanceCoalbed methaneCoalbed methaneCoal geologyCoalbed methaneCoalbed methaneSuppressed reflectanceVitrinite reflectanceCoal explorationCoal geologyCoal geologyMacerals in reflected white lightCoal geologyCoalbed methaneMacerals in reflected white lightQuantitative fluorescenceQuantitative fluorescenceVisual kerogen analysisQuantitative fluorescenceQuantitative fluorescenceVisual kerogen analysisQuantitative fluorescenceQuantitative fluorescenceCoal geologyCoal as oil source rockConversion (liquefaction and gasification)Coalbed methaneCoal explorationCoal as oil source rockCoal geologyCoalbed methaneSolid hydrocarbonsCoal geologyCoalbed methaneCoalbed methaneCoal geology

Coal chemistryCoal geologyCO2 sequestrationCO2 sequestrationCoalbed methaneCombustionOil shaleMacerals in reflected white lightMacerals in reflected white lightQuantitative fluorescenceMacerals in reflected white lightMacerals in reflected white lightMacerals in reflected white lightCoal explorationCombustionCoal geologySuppressed reflectanceVitrinite reflectanceSuppressed reflectanceEffects of overpressure on vitrinite reflectanceSuppressed reflectanceVisual kerogen analysisCarbonizationCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoal chemistryCoalbed methaneCoalbed methaneCO2 sequestrationCO2 sequestrationCoalbed methaneCoal chemistryCoal chemistryCoal chemistryQuantitative fluorescenceMinerals in coalVitrinite reflectanceCoalbed methane

Coal chemistryCarbonizationCarbonizationVitrinite reflectanceVitrinite reflectanceCarbonizationCoalbed methaneCO2 sequestrationVisual kerogen analysisVisual kerogen analysisVisual kerogen analysisVisual kerogen analysisQuantitative fluorescenceCoal geologyVisual kerogen analysisRock-Eval pyrolysisCoal explorationCoal chemistryCoal chemistryCoal geologyMacerals in reflected white lightMinerals in coalMinerals in coalVisual kerogen analysisCombustionCombustionCoal geologyCoalbed methaneCoalbed methaneMinerals in coalSolid hydrocarbonsCoal chemistryCoal geologyCoal chemistryMacerals in reflected white lightCoal geologyCoal geologyCoal chemistryCoal geologyMacerals in reflected white lightCoal chemistry

Coalbed-methane associated waterCoalbed methaneCombustionCombustionCoal explorationCoal chemistryCoal geologyCoal geologyCoal geologyVitrinite reflectanceCarbonizationCO2 sequestrationCoalbed methaneEffects of overpressure on vitrinite reflectanceSuppressed reflectanceCO2 sequestrationCoal geologyCoal geologyCoal geologyCoal geologyCoal geologyCoal geologyCoal geologyCoal geologyCoal as oil source rockConversion (liquefaction and gasification)Coalbed methaneCO2 sequestrationSequestration in shalesSolid hydrocarbonsCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoal as oil source rockConversion (liquefaction and gasification)Coalbed methaneMacerals in reflected white lightMacerals in reflected white lightCoal explorationCoal exploration

CO2 sequestrationKerogen isolationZooclast reflectanceZooclast reflectanceCoal explorationRock-Eval pyrolysisCoal as oil source rockVitrinite reflectanceCoalbed methaneCoal chemistryCoalbed methaneCoalbed methaneCoalbed methaneMinerals in coalCoal chemistryCoal mine methaneCoalbed methaneCombustionKerogen isolationCombustionConversion (liquefaction and gasification)Visual kerogen analysisCoal chemistryCoal chemistryCombustionCoalbed methaneCoal explorationVitrinite reflectanceVitrinite reflectanceCarbonizationCarbonizationCoal explorationCO2 sequestrationCoalbed methaneCO2 sequestrationCO2 sequestrationCO2 sequestrationCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methane

Coal chemistryCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoal explorationCoal chemistryCO2 sequestrationCombustionCoal geologyCoal geologyCoalbed methaneCO2 sequestrationCoal geologyMacerals in reflected white lightWeathering and oxidationCoal geologyCoal explorationCoal geologyCoal as oil source rockVisual kerogen analysisCoal as oil source rockCoal geologyCoalbed methaneCoalbed methaneCoalbed methaneCoal chemistryCombustionVitrinite reflectanceVitrinite reflectanceVitrinite reflectanceVitrinite reflectanceCombustionConversion (liquefaction and gasification)Coal geologyCoal chemistryConversion (liquefaction and gasification)CombustionMacerals in reflected white lightCoal chemistryCombustion

Macerals in reflected white lightCombustionCoal chemistryCombustionCombustionVitrinite reflectanceVitrinite reflectanceMacerals in reflected white lightCoal chemistryCoal geologyCoal chemistryMacerals in reflected white lightMacerals in reflected white lightCoal chemistryMacerals in reflected white lightMacerals in reflected white lightCoal chemistryCombustionMinerals in coalCombustionMacerals in reflected white lightVitrinite reflectanceMacerals in reflected white lightCombustionZooclast reflectanceMacerals in reflected white lightCombustionCoal chemistryCoal chemistryMacerals in reflected white lightCoal chemistryMacerals in reflected white lightCombustionMacerals in reflected white lightMacerals in reflected white lightMacerals in reflected white lightCombustionCombustionCombustionCombustionCarbonization

CombustionMacerals in reflected white lightMacerals in reflected white lightCombustionCombustionCoal chemistryCoal chemistryCombustionCombustionCombustionCombustionCarbonizationCombustionCoal chemistryMacerals in reflected white lightMacerals in reflected white lightMacerals in reflected white lightCombustionCombustionMacerals in reflected white lightMacerals in reflected white lightMacerals in reflected white lightMacerals in reflected white lightCoal geologyCoal chemistryCombustionConversion (liquefaction and gasification)Macerals in reflected white lightCoal chemistryMacerals in reflected white lightCoal chemistryCoal chemistryCoal chemistryCombustionCoal chemistryMacerals in reflected white lightCombustionMacerals in reflected white lightConversion (liquefaction and gasification)Conversion (liquefaction and gasification)Conversion (liquefaction and gasification)

CombustionVitrinite reflectanceVitrinite reflectanceCombustionCombustionCombustionCoal chemistryVitrinite reflectanceCombustionCombustionCombustionCombustionCombustionCombustionConversion (liquefaction and gasification)Coal chemistryMacerals in reflected white lightCoalbed methaneCoal chemistryCoal as oil source rockCoalbed methaneVitrinite reflectanceSuppressed reflectanceCoalbed methaneCoal as oil source rockCoal as oil source rockSolid hydrocarbonsCoal geologyMacerals in reflected white lightCombustionWeathering and oxidationCombustionMinerals in coalWeathering and oxidationCoal chemistryCoal chemistryMinerals in coalWeathering and oxidationWeathering and oxidationCoal chemistryCoal chemistry

Effects of overpressure on vitrinite reflectanceCoal explorationCO2 sequestrationCoalbed methaneSolid hydrocarbonsSolid hydrocarbonsSolid hydrocarbonsCoal as oil source rockGeneral references Suppressed reflectanceRock-Eval pyrolysisSolid hydrocarbonsMacerals in reflected white lightCoal chemistryCoal geologyCoal geologyMacerals in reflected white lightVitrinite reflectanceSolid hydrocarbonsCombustionConversion (liquefaction and gasification)Conversion (liquefaction and gasification)Fluorescence microscopyCoal as oil source rockFluorescence microscopyVisual kerogen analysisOil shaleOil shaleOil shaleVisual kerogen analysisVisual kerogen analysisOil shaleOil shaleOil shaleOil shaleVisual kerogen analysisOil shaleVisual kerogen analysisOil shaleVisual kerogen analysisOil shale

Visual kerogen analysisVisual kerogen analysisVisual kerogen analysisOil shaleSuppressed reflectanceVitrinite reflectanceOil shaleMacerals in reflected white lightOil shaleConversion (liquefaction and gasification)Vitrinite reflectanceVitrinite reflectanceCO2 sequestrationCoalbed methaneCoal as oil source rockBitumen reflectanceSolid hydrocarbonsOil shaleCoalbed methaneVitrinite relectance analysisCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoal chemistryKerogen isolationMacerals in reflected white lightMacerals in reflected white lightMacerals in reflected white lightFluorescence microscopyMacerals in reflected white lightMacerals in reflected white lightMacerals in reflected white lightMacerals in reflected white lightMacerals in reflected white lightCoalbed methaneCombustionSuppressed reflectanceWeathering and oxidationSuppressed reflectanceCarbonization

CarbonizationRock-Eval pyrolysisGeneral references Macerals in reflected white lightWeathering and oxidationMacerals in reflected white lightCoal geologyChemistry of coal maceralsCoal chemistryCoalbed methaneCombustionCoalbed methaneCoalbed methaneCoalbed methaneWeathering and oxidationCoal as oil source rockCarbonizationCombustionCoalbed methaneCoal mine methaneCoal geologyCO2 sequestrationCoalbed methaneCombustionCoal chemistryCombustionCarbonizationCarbonizationWeathering and oxidationCarbonizationSolid hydrocarbonsZooclast reflectanceCoalbed-methane associated waterSolid hydrocarbonsSolid hydrocarbonsSolid hydrocarbonsBitumen reflectanceBitumen reflectanceSolid hydrocarbonsBitumen reflectanceSolid hydrocarbons

Solid hydrocarbonsCoal explorationRock-Eval pyrolysisCoal chemistryVisual kerogen analysisVisual kerogen analysisWeathering and oxidationWeathering and oxidationWeathering and oxidationVitrinite reflectanceCoal explorationCoalbed-methane associated waterCoalbed methaneCombustionSolid hydrocarbonsCoal geologyRock-Eval pyrolysisRock-Eval pyrolysisCarbonizationConversion (liquefaction and gasification)Mineral matrix effectsRock-Eval pyrolysisVitrinite reflectanceCoal geologyCoal geologyCoal geologyCoal geologyCoal geologyCoal explorationVisual kerogen analysisCoal as oil source rockCoalbed methaneCoalbed methaneCoalbed methaneMinerals in coalCoalbed methaneWeathering and oxidationOil shaleCoalbed methaneCombustionSuppressed reflectance

Coalbed methaneCombustionCoalbed methaneOil shaleCO2 sequestrationOil shaleOil shaleCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneVitrinite reflectanceWeathering and oxidationCoalbed methaneOil shaleOil shaleOil shaleOil shaleOil shaleCoalbed methaneCoalbed methaneCoalbed methaneCoal explorationCoal explorationCoalbed methaneCoal as oil source rockMacerals in reflected white lightCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCO2 sequestrationVitrinite reflectanceMacerals in reflected white lightVitrinite reflectanceMineral matrix effectsVitrinite reflectanceVitrinite reflectanceCoal geologyCoal chemistryCombustion

Coalbed methaneCoalbed methaneCombustionCombustionCoal as oil source rockRock-Eval pyrolysisVisual kerogen analysisVisual kerogen analysisCoalbed methaneVitrinite relectance analysisVisual kerogen analysisCombustionMacerals in reflected white lightMacerals in reflected white lightMacerals in reflected white lightMacerals in reflected white lightMacerals in reflected white lightKerogen isolationMacerals in reflected white lightMacerals in reflected white lightCoal geologyMinerals in coalCoalbed methaneCO2 sequestrationCoal chemistryMacerals in reflected white lightMacerals in reflected white lightConversion (liquefaction and gasification)Conversion (liquefaction and gasification)Coalbed methaneCoalbed methaneVitrinite reflectanceCO2 sequestrationCombustionCombustionCoalbed methaneCoalbed methaneConversion (liquefaction and gasification)CarbonizationChemistry of coal maceralsMacerals in reflected white light

Coalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCombustionWeathering and oxidationCoalbed methaneCoal geologyCoalbed methaneSuppressed reflectanceVitrinite reflectanceCoal geologyConversion (liquefaction and gasification)Oil shaleSuppressed reflectanceVitrinite reflectanceSuppressed reflectanceVitrinite reflectanceVitrinite reflectanceConversion (liquefaction and gasification)Conversion (liquefaction and gasification)Coalbed methaneCoalbed methaneCombustionConversion (liquefaction and gasification)Quantitative fluorescenceSuppressed reflectanceMacerals in reflected white lightCoal geologyCoal geologyCoalbed methaneCombustionCombustionCarbonizationCoal chemistryCoal chemistryCO2 sequestrationSequestration in shalesVisual kerogen analysis

Visual kerogen analysisCoal mine methaneCO2 sequestrationCO2 sequestrationCoal mine methaneCoal mine methaneCoal mine methaneCoalbed methaneCoal mine methaneCoalbed methaneCoalbed methaneCO2 sequestrationCoalbed methaneCoal mine methaneCoal mine methaneCoal mine methaneCoalbed methaneCoalbed methaneCoal mine methaneSolid hydrocarbonsCombustionCoal chemistryCoal chemistryCombustionCombustionCoal chemistryCoal chemistryCoal chemistryOil shaleCombustionOil shaleRock-Eval pyrolysisCoal as oil source rockCoal as oil source rockVitrinite reflectanceCO2 sequestrationCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methane

Oil shaleCO2 sequestrationSolid hydrocarbonsCoal chemistryCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneZooclast reflectanceCoalbed methaneCoal geologyConversion (liquefaction and gasification)Macerals in reflected white lightMacerals in reflected white lightMacerals in reflected white lightCoal chemistrySolid hydrocarbonsWeathering and oxidationCoal chemistryVisual kerogen analysisCoal chemistryMacerals in reflected white lightCO2 sequestrationCO2 sequestrationSolid hydrocarbonsSolid hydrocarbonsSolid hydrocarbonsCoalbed methaneSolid hydrocarbonsSolid hydrocarbonsCoalbed methaneCoalbed methaneQuantitative fluorescenceCoal as oil source rockCoal as oil source rockQuantitative fluorescenceFluorescence microscopyCoal as oil source rockCoal as oil source rockWeathering and oxidationQuantitative fluorescence

Bitumen reflectanceQuantitative fluorescenceMineral matrix effectsEffects of overpressure on vitrinite reflectanceVitrinite reflectanceCarbonizationCO2 sequestrationSequestration in shalesCoalbed methaneCarbonizationSolid hydrocarbonsVitrinite reflectanceVitrinite reflectanceVitrinite reflectanceVitrinite relectance analysisCoal as oil source rockVitrinite reflectanceCoal as oil source rockCoal as oil source rockGeneral references Coal as oil source rockCoal as oil source rockCoal as oil source rockCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCombustionCoalbed methaneCombustionCombustionCombustionCoalbed methaneCoalbed methaneCoalbed methaneSolid hydrocarbonsMinerals in coalMinerals in coalSolid hydrocarbonsSolid hydrocarbons

Solid hydrocarbonsKerogen isolationVisual kerogen analysisVisual kerogen analysisCoalbed methaneCoalbed-methane associated waterCarbonizationCoal as oil source rockCO2 sequestrationSolid hydrocarbonsCoalbed methaneCoalbed methaneCoalbed methaneWeathering and oxidationCarbonizationCO2 sequestrationKerogen isolationConversion (liquefaction and gasification)CombustionMacerals in reflected white lightCoalbed methaneCoalbed methaneCoalbed-methane associated waterCoal geologyCoal geologyCoal geologyCoal geologyCoal geologyCoal geologyCoal chemistryWeathering and oxidationSolid hydrocarbonsMacerals in reflected white lightCO2 sequestrationCO2 sequestrationCO2 sequestrationCO2 sequestrationOil shaleCoal explorationCoalbed methaneVitrinite reflectance

Macerals in reflected white lightCoalbed methaneCoalbed methaneCoalbed methaneCoal as oil source rockCarbonizationCO2 sequestrationCoal chemistryMinerals in coalCoal geologyCoal chemistryWeathering and oxidationCoal chemistryCoal chemistryCombustionVitrinite reflectanceVitrinite reflectanceMacerals in reflected white lightVitrinite reflectanceVitrinite reflectanceCoal chemistryCO2 sequestrationCO2 sequestrationCoal chemistryCoalbed methaneConversion (liquefaction and gasification)Visual kerogen analysisMinerals in coalMinerals in coalCoal chemistryOil shaleCoal geologyMacerals in reflected white lightCoal geologyMacerals in reflected white lightMacerals in reflected white lightCoal geologyCarbonizationMacerals in reflected white lightCarbonizationRock-Eval pyrolysis

Coal geologyCoal geologyMinerals in coalCombustionCombustionCarbonizationCoalbed methaneCoalbed methaneCoalbed methaneVitrinite reflectanceMinerals in coalKerogen isolationCoalbed methaneVitrinite reflectanceCoal chemistryCoal geologySolid hydrocarbonsCoalbed methaneWeathering and oxidationConversion (liquefaction and gasification)CO2 sequestrationCoalbed methaneMacerals in reflected white lightMacerals in reflected white lightVisual kerogen analysisCarbonizationVitrinite reflectanceMacerals in reflected white lightVitrinite reflectanceMacerals in reflected white lightFluorescence microscopyWeathering and oxidationCombustionCarbonizationCarbonizationCarbonizationCoal as oil source rockCombustionChemistry of coal maceralsMacerals in reflected white lightVitrinite reflectance

CombustionCoal chemistryVitrinite reflectanceCoal as oil source rockCoal geologyOil shaleCO2 sequestrationCoalbed methaneCoalbed methaneOil shaleZooclast reflectanceCO2 sequestrationCO2 sequestrationCoalbed methaneCoal geologyVitrinite reflectanceVitrinite relectance analysisCarbonizationCombustionMacerals in reflected white lightVitrinite reflectanceVitrinite reflectanceCO2 sequestrationCoal chemistryVitrinite reflectanceSolid hydrocarbonsRock-Eval pyrolysisCO2 sequestrationSequestration in shalesMacerals in reflected white lightCoal mine methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoal geologyMacerals in reflected white lightCoal geology

Macerals in reflected white lightWeathering and oxidationCoalbed methaneVitrinite reflectanceCoal chemistryWeathering and oxidationCoal geologyWeathering and oxidationVitrinite reflectanceWeathering and oxidationCoal chemistryBitumen reflectanceSolid hydrocarbonsQuantitative fluorescenceQuantitative fluorescenceQuantitative fluorescenceCoalbed methaneCombustionCoalbed methaneCoalbed methaneCoalbed methaneVitrinite reflectanceCoalbed methaneCoal geologyCoal geologyMacerals in reflected white lightMacerals in reflected white lightMacerals in reflected white lightMacerals in reflected white lightCoal geologyRock-Eval pyrolysisCoalbed methaneCoalbed-methane associated waterVisual kerogen analysisMacerals in reflected white lightVisual kerogen analysisVisual kerogen analysisCO2 sequestrationCoalbed methaneCoal chemistryVitrinite reflectance

Visual kerogen analysisRock-Eval pyrolysisSuppressed reflectanceCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoal as oil source rockCoalbed methaneCoalbed methaneVitrinite reflectanceCoalbed methaneCoalbed-methane associated waterCO2 sequestrationCO2 sequestrationCoalbed methaneCoalbed methaneCoalbed methaneVitrinite reflectanceSuppressed reflectanceVitrinite reflectanceVitrinite reflectanceCO2 sequestrationCO2 sequestrationConversion (liquefaction and gasification)CombustionKerogen isolationCoalbed methaneEffects of overpressure on vitrinite reflectanceZooclast reflectanceCoal geologyCoalbed methaneCoal geologyCoal chemistryCombustionVitrinite reflectanceMacerals in reflected white lightCoal chemistry

CombustionVitrinite reflectanceSolid hydrocarbonsCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneRock-Eval pyrolysisCoalbed methaneSuppressed reflectanceVitrinite reflectanceCoalbed methaneVitrinite reflectanceVitrinite reflectanceVitrinite reflectanceCoal geologyVitrinite reflectanceMacerals in reflected white lightSolid hydrocarbonsCoalbed methaneVisual kerogen analysisSuppressed reflectanceWeathering and oxidationCoal as oil source rockCoal chemistryCO2 sequestrationCoalbed methaneVitrinite reflectanceWeathering and oxidationRock-Eval pyrolysisVisual kerogen analysisCoalbed methaneCoalbed methaneCO2 sequestrationCoalbed methaneCoalbed methaneCoal explorationCoal chemistryCoal chemistry

CarbonizationCO2 sequestrationCoal chemistryCoal as oil source rockCoal as oil source rockOil shaleCoal as oil source rockCoalbed methaneCoal mine methaneCombustionCoal chemistryMacerals in reflected white lightCO2 sequestrationCoalbed methaneCoal chemistryCombustionCombustionMacerals in reflected white lightMinerals in coalMinerals in coalChemistry of coal maceralsCoal chemistryMacerals in reflected white lightSolid hydrocarbonsCoal mine methaneKerogen isolationOil shaleVitrinite reflectanceFluorescence microscopyQuantitative fluorescenceFluorescence microscopyQuantitative fluorescenceFluorescence microscopyQuantitative fluorescenceFluorescence microscopyConversion (liquefaction and gasification)Coalbed methaneMinerals in coalZooclast reflectanceZooclast reflectanceWeathering and oxidation

Kerogen isolationVitrinite reflectanceCoal chemistryWeathering and oxidationCoal as oil source rockCoalbed methaneCoal as oil source rockCoal as oil source rockCoal as oil source rockMacerals in reflected white lightCoal as oil source rockVitrinite reflectanceWeathering and oxidationKerogen isolationMacerals in reflected white lightCoalbed methaneCoalbed methaneOil shaleCO2 sequestrationZooclast reflectanceMacerals in reflected white lightCoalbed methaneCoal chemistryCoalbed methaneCombustionCoalbed methaneCoalbed methaneCO2 sequestrationCoalbed methaneCoalbed methaneCombustionMacerals in reflected white lightCoalbed methaneCO2 sequestrationCoalbed methaneCoal mine methaneCoal chemistryCoal chemistryCoal chemistryQuantitative fluorescenceVisual kerogen analysis

Vitrinite reflectanceVitrinite reflectanceMacerals in reflected white lightVitrinite reflectanceSuppressed reflectanceVitrinite reflectanceSuppressed reflectanceWeathering and oxidationSuppressed reflectanceSolid hydrocarbonsCoalbed methaneCoalbed methaneCoalbed methaneSolid hydrocarbonsCoalbed methaneCoal chemistryWeathering and oxidationMinerals in coalCoal chemistryCombustionMinerals in coalCoal geologyVisual kerogen analysisCoal geologyCoalbed methaneKerogen isolationWeathering and oxidationCoal chemistryMacerals in reflected white lightCoal chemistryCO2 sequestrationCO2 sequestrationCoal as oil source rockCoal chemistryCoalbed methaneOil shaleCoal mine methaneSolid hydrocarbonsCoal geologyWeathering and oxidationCoal chemistry

Coal chemistrySolid hydrocarbonsCoal chemistrySamplingCoal explorationCoalbed methaneCO2 sequestrationCO2 sequestrationCO2 sequestrationCO2 sequestrationCoalbed methaneCoalbed methaneCombustionCarbonizationCoal explorationMacerals in reflected white lightCoalbed methaneCoalbed methaneMacerals in reflected white lightMacerals in reflected white lightMacerals in reflected white lightCoal geologyCoal geologyCoal geologyCoal geologyCoal geologyMacerals in reflected white lightMacerals in reflected white lightCoalbed methaneMinerals in coalCoal chemistryCoal geologyCoal geologyMinerals in coalCoal ballsCoal geologyMacerals in reflected white lightCoal ballsMacerals in reflected white lightMacerals in reflected white lightCoal geology

Macerals in reflected white lightMinerals in coalCoal geologyCoal geologyCoalbed methaneCoalbed methaneOil shaleVisual kerogen analysisVisual kerogen analysisCoal as oil source rockCoal geologyFluorescence microscopyMacerals in reflected white lightMinerals in coalCarbonizationMinerals in coalCarbonizationCarbonizationMacerals in reflected white lightCoalbed methaneVisual kerogen analysisCoal chemistryCoal chemistryVitrinite reflectanceCoalbed methaneCO2 sequestrationCoalbed methaneCO2 sequestrationCO2 sequestrationCO2 sequestrationCoal chemistryCoalbed methaneZooclast reflectanceZooclast reflectanceVitrinite reflectanceVitrinite relectance analysisVitrinite reflectanceCoalbed methaneCoalbed methaneCoalbed methaneCoal geology

Coal ballsCoal ballsCoal ballsSolid hydrocarbonsSolid hydrocarbonsMinerals in coalCarbonizationCombustionWeathering and oxidationRock-Eval pyrolysisCO2 sequestrationCombustionCombustionCombustionCoal explorationCoal geologyCoal geologyMacerals in reflected white lightCoal geologyCoal geologyMacerals in reflected white lightWeathering and oxidationVitrinite reflectanceWeathering and oxidationVitrinite reflectanceCombustionCO2 sequestrationCoalbed methaneCombustionCO2 sequestrationCoal chemistryCoalbed methaneCoalbed methaneSolid hydrocarbonsCO2 sequestrationCarbonizationCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methane

Coalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCombustionCombustionMacerals in reflected white lightCarbonizationCoal as oil source rockCoalbed methaneSolid hydrocarbonsCarbonizationCarbonizationCarbonizationCarbonizationCarbonizationCarbonizationSolid hydrocarbonsMacerals in reflected white lightMacerals in reflected white lightMacerals in reflected white lightCarbonizationMacerals in reflected white lightZooclast reflectanceQuantitative fluorescenceZooclast reflectanceVitrinite reflectanceCarbonizationCoal chemistryCoal chemistryVitrinite reflectanceGeneral references Quantitative fluorescenceWeathering and oxidationMinerals in coalMinerals in coalCoal chemistryCoal chemistryCoalbed methaneCoal geology

Oil shaleOil shaleSolid hydrocarbonsVisual kerogen analysisWeathering and oxidationWeathering and oxidationWeathering and oxidationConversion (liquefaction and gasification)CO2 sequestrationCoalbed methaneVisual kerogen analysisCoalbed methaneCO2 sequestrationConversion (liquefaction and gasification)Suppressed reflectanceVisual kerogen analysisVitrinite reflectanceVisual kerogen analysisCoalbed methaneVitrinite reflectanceCoalbed methaneCoal chemistryCoalbed methaneVitrinite reflectanceCoal chemistryCombustionCoal chemistryCO2 sequestrationCoalbed methaneCO2 sequestrationFluorescence microscopyVisual kerogen analysisMacerals in reflected white lightCoal chemistryCoal chemistryCoal chemistryCO2 sequestrationCoalbed methaneCoalbed methaneChemistry of coal maceralsCoal chemistry

Coal chemistrySolid hydrocarbonsCoal chemistryChemistry of coal maceralsCoal chemistryChemistry of coal maceralsCoal chemistryVitrinite reflectanceVitrinite reflectanceChemistry of coal maceralsCoal chemistryChemistry of coal maceralsCoal chemistryVitrinite reflectanceMacerals in reflected white lightChemistry of coal maceralsCoal chemistryChemistry of coal maceralsCoal chemistryMacerals in reflected white lightCO2 sequestrationCoalbed methaneCO2 sequestrationCombustionMacerals in reflected white lightChemistry of coal maceralsCoal chemistryMacerals in reflected white lightSuppressed reflectanceVitrinite reflectanceChemistry of coal maceralsCoal chemistrySolid hydrocarbonsChemistry of coal maceralsCoal chemistryMacerals in reflected white lightVitrinite reflectanceCoalbed methaneWeathering and oxidationCarbonizationCoal as oil source rock

Coal chemistryWeathering and oxidationCarbonizationCoalbed methaneOil shaleOil shaleCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCO2 sequestrationCoalbed methaneCoalbed methaneCoalbed methaneSolid hydrocarbonsVitrinite reflectanceCoalbed methaneCoal chemistryMinerals in coalCO2 sequestrationCoalbed methaneCoalbed methaneCO2 sequestrationCombustionVitrinite reflectanceCoal as oil source rockSolid hydrocarbonsMacerals in reflected white lightCoal explorationCoal explorationCoal geologyCoal geologyCoal geologyCoal geologyCoal geologyCoal explorationCoal geologyCoal geologyCoalbed methane

Coalbed methaneGeneral references Vitrinite reflectanceMacerals in reflected white lightVitrinite reflectanceVitrinite reflectanceVitrinite relectance analysisVitrinite reflectanceCoalbed methaneSolid hydrocarbonsCoalbed methaneVitrinite reflectanceCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoal geologyCoalbed methaneCoalbed methaneCoalbed methaneCombustionCoalbed methaneMacerals in reflected white lightQuantitative fluorescenceWeathering and oxidationCO2 sequestrationCoalbed methaneCoalbed methaneCO2 sequestrationCoalbed methaneCoalbed methaneCoal geologyCoal geologyCoal geologyCoalbed methaneCoalbed methaneCoalbed-methane associated waterCoalbed methaneCO2 sequestrationFluorescence microscopyVisual kerogen analysis

Effects of overpressure on vitrinite reflectanceSuppressed reflectanceVitrinite reflectanceEffects of overpressure on vitrinite reflectanceSuppressed reflectanceCO2 sequestrationCO2 sequestrationCoalbed methaneCoalbed methaneCombustionCombustionCoalbed methaneCoalbed methaneEffects of overpressure on vitrinite reflectanceVitrinite reflectanceCO2 sequestrationCO2 sequestrationCoal mine methaneCoalbed methaneCO2 sequestrationCO2 sequestrationKerogen isolationVitrinite reflectanceKerogen isolationQuantitative fluorescenceVitrinite reflectanceKerogen isolationVitrinite reflectanceKerogen isolationCoal geologyMacerals in reflected white lightVisual kerogen analysisCombustionOil shaleOil shaleOil shaleOil shaleOil shaleCoal geologyCoal geologyCombustion

Conversion (liquefaction and gasification)Rock-Eval pyrolysisCoal explorationCoal chemistrySolid hydrocarbonsCoal chemistryCoal geologyCoalbed methaneCO2 sequestrationSolid hydrocarbonsCombustionCoal chemistryCoalbed methaneCO2 sequestrationCoalbed methaneCoal as oil source rockCoalbed methaneQuantitative fluorescenceQuantitative fluorescenceVitrinite reflectanceVitrinite reflectanceCoalbed methaneCoal chemistryRock-Eval pyrolysisCoalbed methaneCoal geologyConversion (liquefaction and gasification)Coalbed methaneCoal explorationCoalbed methaneMacerals in reflected white lightCoal explorationCoal explorationCoalbed methaneConversion (liquefaction and gasification)Conversion (liquefaction and gasification)Coal chemistryWeathering and oxidationCombustionConversion (liquefaction and gasification)CO2 sequestration

Solid hydrocarbonsCoal as oil source rockCO2 sequestrationCoal geologyMacerals in reflected white lightQuantitative fluorescenceMacerals in reflected white lightCombustionMacerals in reflected white lightCombustionMacerals in reflected white lightQuantitative fluorescenceCombustionCoal mine methaneCoalbed methaneCombustionConversion (liquefaction and gasification)Quantitative fluorescenceWeathering and oxidationQuantitative fluorescenceWeathering and oxidationConversion (liquefaction and gasification)Coalbed methaneCO2 sequestrationCoalbed methaneCombustionCoalbed methaneCoalbed methaneCoal as oil source rockCarbonizationCarbonizationCoalbed methaneCO2 sequestrationCoalbed methaneSolid hydrocarbonsConversion (liquefaction and gasification)Coalbed methaneCoalbed methaneCoalbed methaneConversion (liquefaction and gasification)Coalbed methane

Coal geologyCoal chemistryMinerals in coalMacerals in reflected white lightOil shaleCoal geologyCoal explorationCoal geologyCoal geologyCoal chemistryCoal geologyCoalbed methaneCoal geologyCoal geologyMacerals in reflected white lightSamplingCoal geologyMacerals in reflected white lightCoalbed methaneCoal geologyCoal geologyCarbonizationMacerals in reflected white lightMacerals in reflected white lightMacerals in reflected white lightMacerals in reflected white lightCO2 sequestrationCO2 sequestrationCO2 sequestrationOil shaleCO2 sequestrationOil shaleCO2 sequestrationCoalbed methaneCombustionVitrinite reflectanceCO2 sequestrationCombustionCoalbed methaneCoalbed methaneCoalbed methane

Weathering and oxidationSolid hydrocarbonsVisual kerogen analysisKerogen isolationCarbonizationCoal chemistryMinerals in coalCombustionConversion (liquefaction and gasification)Oil shaleCoalbed methaneConversion (liquefaction and gasification)Coal chemistrySolid hydrocarbonsCoal chemistryVisual kerogen analysisVisual kerogen analysisCoal explorationVitrinite reflectanceCoalbed methaneCoalbed methaneCoalbed methaneMacerals in reflected white lightVisual kerogen analysisCoal as oil source rockVitrinite relectance analysisSuppressed reflectanceVitrinite reflectanceSuppressed reflectanceVitrinite reflectanceVitrinite relectance analysisFluorescence microscopyMacerals in reflected white lightVitrinite relectance analysisVitrinite reflectanceRock-Eval pyrolysisCombustionCombustionVisual kerogen analysisVisual kerogen analysisCoal as oil source rock

Coal as oil source rockCoal geologyCoalbed methaneCoal as oil source rockMacerals in reflected white lightCoalbed methaneCoal explorationCoalbed methaneCoal geologyVitrinite reflectanceCoal chemistryVitrinite reflectanceMacerals in reflected white lightMacerals in reflected white lightCarbonizationVitrinite reflectanceFluorescence microscopyCoal as oil source rockMacerals in reflected white lightSuppressed reflectanceVitrinite reflectanceCarbonizationVitrinite reflectanceMacerals in reflected white lightVitrinite reflectanceMineral matrix effectsSuppressed reflectanceCoal chemistrySolid hydrocarbonsCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoal mine methane

CO2 sequestrationCoal chemistryCombustionCoal geologyCoal geologyCombustionCarbonizationMacerals in reflected white lightMacerals in reflected white lightWeathering and oxidationCombustionCoalbed methaneCO2 sequestrationCoalbed methaneCoalbed methaneVisual kerogen analysisMinerals in coalCombustionCoal chemistryConversion (liquefaction and gasification)Conversion (liquefaction and gasification)Vitrinite reflectanceMacerals in reflected white lightConversion (liquefaction and gasification)Vitrinite relectance analysisCoal chemistryConversion (liquefaction and gasification)Coal geologyMacerals in reflected white lightMacerals in reflected white lightConversion (liquefaction and gasification)Coalbed methaneCoalbed methaneWeathering and oxidationCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methane

Coalbed methaneWeathering and oxidationCoalbed methaneCombustionCombustionCoal geologyCO2 sequestrationMinerals in coalCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCO2 sequestrationSuppressed reflectanceSuppressed reflectanceVitrinite reflectanceCoal as oil source rockCoal as oil source rockCoal as oil source rockVitrinite reflectanceCoal as oil source rockCoal as oil source rockCoal as oil source rockSuppressed reflectanceConversion (liquefaction and gasification)Coalbed methane

Coalbed methaneCoal chemistryCoal geologyCoalbed methaneCO2 sequestrationCoalbed methaneCoal chemistryMacerals in reflected white lightCoal chemistrySolid hydrocarbonsSolid hydrocarbonsCoal mine methaneCoal as oil source rockCoalbed methaneVitrinite reflectanceVisual kerogen analysisCoalbed methaneCombustionCarbonizationCoal chemistryCarbonizationCO2 sequestrationCO2 sequestrationOil shaleCoal geologyCoalbed methaneConversion (liquefaction and gasification)Coalbed methaneCoalbed methaneSuppressed reflectanceVitrinite reflectanceWeathering and oxidationCO2 sequestrationSequestration in shalesSequestration in shalesCO2 sequestrationSequestration in shalesCarbonizationConversion (liquefaction and gasification)Vitrinite reflectanceVitrinite relectance analysis

Weathering and oxidationOil shaleCoal geologyMacerals in reflected white lightKerogen isolationMacerals in reflected white lightCombustionCoal chemistryMacerals in reflected white lightCoalbed methaneCoalbed-methane associated waterSolid hydrocarbonsCoal as oil source rockCoal as oil source rockZooclast reflectanceZooclast reflectanceZooclast reflectanceCO2 sequestrationCO2 sequestrationCoal geologyCoalbed methaneConversion (liquefaction and gasification)Bitumen reflectanceCoalbed methaneCoalbed methaneCombustionMacerals in reflected white lightConversion (liquefaction and gasification)Coalbed methaneCO2 sequestrationCoalbed methaneCoalbed methaneCoal explorationCoal explorationCO2 sequestrationMinerals in coalCoal chemistryMinerals in coalZooclast reflectanceConversion (liquefaction and gasification)Coal chemistry

Coal mine methaneCoalbed methaneCoalbed methaneCO2 sequestrationCoalbed methaneCoalbed methaneVitrinite reflectanceCoal geologyCoal geologyCoal geologyVitrinite reflectanceCoalbed-methane associated waterCoalbed-methane associated waterCoal geologyRock-Eval pyrolysisRock-Eval pyrolysisCoalbed methaneCoalbed methaneCarbonizationVitrinite reflectanceSuppressed reflectanceVitrinite reflectanceOil shaleQuantitative fluorescenceQuantitative fluorescenceVitrinite reflectanceQuantitative fluorescenceConversion (liquefaction and gasification)Conversion (liquefaction and gasification)CombustionCoalbed methaneWeathering and oxidationCoal as oil source rockCoalbed methaneCoalbed methaneCoalbed methaneCO2 sequestrationCO2 sequestrationCoal mine methaneCoal mine methaneCoal mine methane

Coal mine methaneVisual kerogen analysisMacerals in reflected white lightCoal chemistryCoal geologyOil shaleWeathering and oxidationWeathering and oxidationCoal chemistryCoal chemistrySolid hydrocarbonsCoal chemistryCoal chemistrySamplingCoal chemistryCombustionCoalbed methaneCoalbed methaneCO2 sequestrationCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoal chemistryCoalbed methaneCoalbed methaneCO2 sequestrationCO2 sequestrationCoalbed methaneCO2 sequestrationCoalbed methaneCO2 sequestrationCoalbed methaneCO2 sequestrationCoalbed methaneGeneral references CarbonizationWeathering and oxidationCoalbed methane

General references General references Coalbed methaneCoal explorationCarbonizationCombustionConversion (liquefaction and gasification)Conversion (liquefaction and gasification)Conversion (liquefaction and gasification)Conversion (liquefaction and gasification)Quantitative fluorescenceConversion (liquefaction and gasification)Macerals in reflected white lightMinerals in coalCoal geologyMacerals in reflected white lightSolid hydrocarbonsZooclast reflectanceSolid hydrocarbonsSolid hydrocarbonsSolid hydrocarbonsSolid hydrocarbonsCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoal geologyCoalbed methaneCoal geologyCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methane

Coalbed methaneCO2 sequestrationCoalbed methaneCO2 sequestrationCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed-methane associated waterCoalbed methaneCO2 sequestrationCoalbed methaneCO2 sequestrationCO2 sequestrationCoalbed methaneCO2 sequestrationCoalbed methaneCoalbed methaneFluorescence microscopyQuantitative fluorescenceVisual kerogen analysisMinerals in coalCoalbed methaneCoalbed methaneCarbonizationCarbonizationCombustionConversion (liquefaction and gasification)CarbonizationCarbonizationCarbonizationCarbonizationCarbonizationCoalbed methaneCO2 sequestrationConversion (liquefaction and gasification)Coalbed methaneCoalbed methaneCombustionCombustionKerogen isolation

Macerals in reflected white lightWeathering and oxidationBitumen reflectanceSolid hydrocarbonsMineral matrix effectsCarbonizationWeathering and oxidationWeathering and oxidationVitrinite reflectanceVisual kerogen analysisCoal as oil source rockCarbonizationConversion (liquefaction and gasification)Coalbed methaneVisual kerogen analysisCoalbed methaneCoalbed methaneCoal chemistryCoal as oil source rockCarbonizationCO2 sequestrationCO2 sequestrationCO2 sequestrationCO2 sequestrationMinerals in coalOil shaleConversion (liquefaction and gasification)Coalbed methaneCoalbed methaneCoalbed methaneCombustionCoal explorationCoal geologyRock-Eval pyrolysisGeneral references Rock-Eval pyrolysisGeneral references Vitrinite reflectanceGeneral references Vitrinite reflectanceRock-Eval pyrolysis

Coal as oil source rockCoal explorationCoal geologyCoal geologyMacerals in reflected white lightVitrinite reflectanceCoal as oil source rockCoal geologyCoal as oil source rockCoal as oil source rockSuppressed reflectanceCoal geologyCoal as oil source rockSuppressed reflectanceCoal as oil source rockCoal as oil source rockCoal as oil source rockCoal geologyCoal as oil source rockSuppressed reflectanceCoal as oil source rockCoal as oil source rockVitrinite reflectanceCoal as oil source rockCoal as oil source rockCoal as oil source rockCoal as oil source rockFluorescence microscopyMacerals in reflected white lightSuppressed reflectanceVitrinite reflectanceBitumen reflectanceZooclast reflectanceCoal chemistryCoal as oil source rockCoal geologyCoal as oil source rockCoal geologyCoal as oil source rockCoalbed methaneCoalbed-methane associated water

Coalbed methaneCoalbed methaneWeathering and oxidationWeathering and oxidationWeathering and oxidationCoalbed methaneCoalbed methaneCoalbed methaneCoalbed-methane associated waterWeathering and oxidationCombustionVisual kerogen analysisCoal geologyCoal geologyCoal ballsCoal ballsCoal geologyCoal ballsCoal geologyCoal geologyCoal geologyCoal ballsCoal geologyCoal geologyCoal as oil source rockRock-Eval pyrolysisMacerals in reflected white lightKerogen isolationCombustionCoalbed methaneSamplingCoal as oil source rockMacerals in reflected white lightWeathering and oxidationSuppressed reflectanceCoalbed methaneCO2 sequestrationMinerals in coalVitrinite reflectanceCoalbed methaneCoal exploration

Coal chemistryCoal geologyCoal geologyCoal chemistryCombustionCoal chemistryCoal chemistryCoal chemistryCoal chemistryCarbonizationCoal mine methaneCoalbed methaneCoalbed methaneMinerals in coalCoalbed methaneCombustionQuantitative fluorescenceWeathering and oxidationWeathering and oxidationWeathering and oxidationOil shaleCoalbed methaneVitrinite reflectanceCoalbed methaneCoalbed-methane associated waterCoal geologyCoal geologyVisual kerogen analysisVisual kerogen analysisCarbonizationCoal as oil source rockVitrinite reflectanceCoal geologyCombustionCO2 sequestrationCO2 sequestrationCoalbed methaneSamplingCoalbed methaneCoalbed methaneCoalbed methane

Coalbed methaneCoalbed methaneCO2 sequestrationCoalbed methaneCoalbed methaneCombustionCoal chemistryCombustionSolid hydrocarbonsCoal geologyCoal geologyMacerals in reflected white lightSolid hydrocarbonsGeneral references Zooclast reflectanceCoal as oil source rockCoal as oil source rockVisual kerogen analysisCoal as oil source rockCoal as oil source rockVisual kerogen analysisCoal as oil source rockCoal as oil source rockCoal as oil source rockVisual kerogen analysisVisual kerogen analysisCoal chemistryQuantitative fluorescenceCoal geologyFluorescence microscopyQuantitative fluorescenceQuantitative fluorescenceQuantitative fluorescenceFluorescence microscopyWeathering and oxidationWeathering and oxidationCombustionCoal geologyCombustionVitrinite reflectanceVitrinite reflectance

Coal geologyCoalbed methaneCO2 sequestrationCoalbed methaneCoal chemistryCoal geologyCoal as oil source rockSuppressed reflectanceVitrinite reflectanceEffects of overpressure on vitrinite reflectanceRock-Eval pyrolysisCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneVitrinite reflectanceCoalbed methaneCoalbed methaneCoalbed methaneCombustionCarbonizationCarbonizationCarbonizationVitrinite reflectanceCarbonizationCarbonizationCoal chemistryMacerals in reflected white lightCoal chemistryCoal chemistryCoal chemistryCarbonizationCoal as oil source rockVitrinite reflectanceVitrinite reflectanceBitumen reflectanceCoalbed methaneCombustionCoal chemistryCoal chemistryCoal chemistry

CombustionCombustionCombustionSuppressed reflectanceQuantitative fluorescenceVitrinite reflectanceCombustionCoal chemistryQuantitative fluorescenceWeathering and oxidationSuppressed reflectanceCombustionCoalbed methaneSuppressed reflectanceCombustionCoal chemistryCoalbed methaneCoalbed-methane associated waterCombustionCombustionMinerals in coalCoalbed methaneCoalbed methaneCoal as oil source rockSuppressed reflectanceFluorescence microscopyCoal as oil source rockQuantitative fluorescenceCoalbed methaneCoalbed methaneCO2 sequestrationVisual kerogen analysisCoal geologyCoal explorationCoal geologyCoal geologyCombustionCoal explorationCoalbed methaneCoalbed methaneCoal as oil source rock

Coalbed methaneZooclast reflectanceCarbonizationMinerals in coalSolid hydrocarbonsFluorescence microscopyQuantitative fluorescenceVitrinite reflectanceConversion (liquefaction and gasification)Visual kerogen analysisCoalbed-methane associated waterCoalbed-methane associated waterCombustionCoal ballsCoal geologyCoal ballsCoal ballsCoal chemistryMinerals in coalSuppressed reflectanceVitrinite reflectanceVitrinite reflectanceVitrinite reflectanceCoal chemistryVisual kerogen analysisVisual kerogen analysisVisual kerogen analysisOil shaleCarbonizationVisual kerogen analysisCoalbed-methane associated waterCoalbed methaneCoal ballsCarbonizationCoal chemistryCoal chemistryCoal chemistryCoal chemistryWeathering and oxidationCoal chemistryCoal chemistry

Coalbed methaneCO2 sequestrationCoalbed methaneCO2 sequestrationCO2 sequestrationOil shaleCoal chemistryQuantitative fluorescenceCoalbed methaneSolid hydrocarbonsCarbonizationMacerals in reflected white lightMinerals in coalMinerals in coalMinerals in coalCoal chemistryMacerals in reflected white lightVitrinite reflectanceZooclast reflectanceCoal geologyCO2 sequestrationCoalbed methaneCoalbed methaneCarbonizationWeathering and oxidationCoal mine methaneCombustionCombustionCombustionCombustionCombustionMinerals in coalCombustionCombustionVisual kerogen analysisCoalbed methaneCoalbed-methane associated waterCoalbed methaneCoalbed-methane associated waterCoalbed methaneCoalbed-methane associated water

Coalbed methaneCoalbed methaneCoalbed-methane associated waterCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoal as oil source rockCoalbed methaneCoal geologyMacerals in reflected white lightSolid hydrocarbonsCoalbed methaneConversion (liquefaction and gasification)Kerogen isolationKerogen isolationCoalbed methaneCoal chemistryZooclast reflectanceBitumen reflectanceSolid hydrocarbonsCoalbed methaneCoalbed methaneConversion (liquefaction and gasification)Vitrinite reflectanceCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoal chemistryCoal chemistryCoal chemistryCoal explorationCoal geologyCoal chemistryQuantitative fluorescenceSuppressed reflectanceVitrinite reflectance

Coal chemistryVitrinite reflectanceConversion (liquefaction and gasification)Coal as oil source rockCoalbed methaneSuppressed reflectanceConversion (liquefaction and gasification)Minerals in coalVisual kerogen analysisVisual kerogen analysisVisual kerogen analysisGeneral references Visual kerogen analysisVitrinite relectance analysisCoal chemistryCoal geologyZooclast reflectanceCoalbed methaneCoal geologyCO2 sequestrationCO2 sequestrationCO2 sequestrationCoalbed methaneCoalbed methaneSolid hydrocarbonsCarbonizationConversion (liquefaction and gasification)Conversion (liquefaction and gasification)Kerogen isolationRock-Eval pyrolysisCombustionKerogen isolationKerogen isolationVitrinite reflectanceVisual kerogen analysisCombustionCoal chemistryCoalbed methaneMinerals in coalMinerals in coalCoal exploration

Coalbed methaneCoalbed methaneVisual kerogen analysisSolid hydrocarbonsOil shaleCoalbed methaneCombustionCoal explorationCoal explorationCoal geologyCoal geologyCO2 sequestrationCO2 sequestrationCO2 sequestrationCO2 sequestrationCO2 sequestrationCombustionCoal chemistryCO2 sequestrationCombustionVitrinite reflectanceQuantitative fluorescenceFluorescence microscopyConversion (liquefaction and gasification)Vitrinite reflectanceCarbonizationVitrinite reflectanceMacerals in reflected white lightCoal geologyCoal chemistryCombustionWeathering and oxidationCO2 sequestrationCoalbed methaneSolid hydrocarbonsCoal chemistryCO2 sequestrationSolid hydrocarbonsSolid hydrocarbonsSolid hydrocarbonsSolid hydrocarbons

Solid hydrocarbonsSolid hydrocarbonsCoal chemistryOil shaleCoal as oil source rockCoal mine methaneCombustionCoalbed methaneCoal chemistryCoal chemistryCoal chemistryCoal chemistryMinerals in coalVitrinite reflectanceMinerals in coalCoal explorationOil shaleOil shaleConversion (liquefaction and gasification)Minerals in coalCO2 sequestrationSamplingCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneSuppressed reflectanceVitrinite reflectanceCoal geologyCoal geologyOil shaleCoal geologyCoal geologyOil shaleOil shaleCO2 sequestrationCoalbed methaneCoal mine methaneCO2 sequestrationCoalbed methaneCO2 sequestration

Coalbed methaneKerogen isolationCombustionMinerals in coalCoal explorationCoal chemistryCombustionCombustionCombustionCO2 sequestrationCombustionCombustionCoal chemistryCarbonizationCO2 sequestrationCO2 sequestrationCarbonizationMinerals in coalCarbonizationMinerals in coalCoalbed methaneCoal chemistryCO2 sequestrationCO2 sequestrationCoalbed methaneCoalbed methaneCO2 sequestrationCoalbed methaneCO2 sequestrationCO2 sequestrationCoalbed methaneMineral matrix effectsVisual kerogen analysisCoalbed methaneOil shaleCoal as oil source rockCoalbed-methane associated waterMacerals in reflected white lightCoalbed methaneCoal chemistrySuppressed reflectance

Coal chemistryCombustionCoalbed methaneCoalbed methaneCarbonizationCO2 sequestrationCombustionVitrinite reflectanceConversion (liquefaction and gasification)CO2 sequestrationSolid hydrocarbonsSolid hydrocarbonsSolid hydrocarbonsSolid hydrocarbonsSolid hydrocarbonsVitrinite reflectanceCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneOil shaleCoal explorationCoal chemistryCoalbed methaneCoal as oil source rockKerogen isolationCoal as oil source rockCoal as oil source rockCoalbed methaneCombustionCoalbed methaneCarbonizationCarbonizationMinerals in coalCoal chemistryMinerals in coalCoal geologyMineral matrix effectsVitrinite reflectanceSolid hydrocarbons

Coalbed methaneVitrinite reflectanceOil shaleCombustionWeathering and oxidationWeathering and oxidationKerogen isolationWeathering and oxidationCombustionCoal geologyCoal chemistryBitumen reflectanceSolid hydrocarbonsCoal explorationCoalbed methaneConversion (liquefaction and gasification)Macerals in reflected white lightCoal geologyCoal ballsMacerals in reflected white lightCoal geologyCoal geologyCoal geologyCoal geologyCoal explorationCoal geologyCoal geologyCoal geologyMacerals in reflected white lightCoal geologyCoal ballsMacerals in reflected white lightCoal geologyMacerals in reflected white lightCoal geologySamplingCoalbed methaneCoalbed methaneCoalbed methaneCO2 sequestrationSolid hydrocarbons

Coal geologyCoal chemistryCoal chemistryCoalbed methaneCoalbed methaneCoalbed-methane associated waterCoalbed methaneCoalbed methaneVisual kerogen analysisCoal geologyCoal geologyMacerals in reflected white lightMacerals in reflected white lightCoal geologyMacerals in reflected white lightMacerals in reflected white lightCoal as oil source rockCoal as oil source rockCoal ballsCoal geologyCoal geologyMacerals in reflected white lightCoal geologyVitrinite reflectanceCoal geologyMacerals in reflected white lightMacerals in reflected white lightCoal ballsCoal geologyCoal geologyGeneral references Coalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneVisual kerogen analysisCoalbed methaneCoalbed methane

Coalbed methaneCoalbed-methane associated waterCoalbed methaneCoalbed methaneCoalbed methaneCarbonizationRock-Eval pyrolysisCO2 sequestrationCoalbed methaneVitrinite reflectanceCoal mine methaneSuppressed reflectanceSuppressed reflectanceVitrinite reflectanceCoalbed methaneCoalbed methaneCombustionCoalbed methaneOil shaleMacerals in reflected white lightCoalbed methaneGeneral references Macerals in reflected white lightCoal geologyOil shaleKerogen isolationKerogen isolationVisual kerogen analysisVisual kerogen analysisConversion (liquefaction and gasification)Conversion (liquefaction and gasification)Weathering and oxidationVitrinite reflectanceVitrinite relectance analysisFluorescence microscopyQuantitative fluorescenceFluorescence microscopyVisual kerogen analysisVitrinite reflectanceVitrinite relectance analysisVisual kerogen analysis

Visual kerogen analysisVisual kerogen analysisMacerals in reflected white lightQuantitative fluorescenceCombustionCO2 sequestrationCarbonizationCoal chemistryCoal chemistryCoal chemistryMinerals in coalCoal chemistryCoal chemistryCoalbed methaneCoal geologyConversion (liquefaction and gasification)Coalbed methaneSolid hydrocarbonsRock-Eval pyrolysisVisual kerogen analysisVitrinite reflectanceCoal as oil source rockCoal as oil source rockCoal geologySolid hydrocarbonsWeathering and oxidationCoal chemistryCoal geologyCoal geologyMacerals in reflected white lightCoal geologyCoal geologyCoal geologyCoal geologyCoalbed methaneCarbonizationVisual kerogen analysisVisual kerogen analysisOil shaleVisual kerogen analysisVisual kerogen analysis

Coalbed methaneCoalbed methaneCoalbed methaneCO2 sequestrationCoalbed methaneCoalbed methaneCO2 sequestrationCoalbed methaneMacerals in reflected white lightMacerals in reflected white lightConversion (liquefaction and gasification)Macerals in reflected white lightCombustionConversion (liquefaction and gasification)CombustionConversion (liquefaction and gasification)Conversion (liquefaction and gasification)CombustionConversion (liquefaction and gasification)Coalbed methaneCoalbed methaneConversion (liquefaction and gasification)CO2 sequestrationOil shaleCoal chemistryCoal chemistryCombustionCoal geologyCoal chemistryCoal geologyConversion (liquefaction and gasification)CO2 sequestrationCoalbed methaneCO2 sequestrationSolid hydrocarbonsZooclast reflectanceMinerals in coalMinerals in coalCoal chemistryCombustionCoal geology

Coal geologyCoal mine methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCO2 sequestrationCO2 sequestrationCoalbed methaneCoal explorationCombustionFluorescence microscopyCarbonizationCarbonizationCarbonizationCombustionCoal geologyCoal geologyCoal geologyCoal geologyCoal chemistryCombustionCoal chemistryCombustionMinerals in coalCoal chemistryWeathering and oxidationCO2 sequestrationCO2 sequestrationCoalbed methaneCO2 sequestrationVitrinite reflectanceCO2 sequestrationCoal chemistryVitrinite reflectanceConversion (liquefaction and gasification)Macerals in reflected white lightCombustionOil shaleCoalbed methaneCombustion

CombustionCombustionCoal chemistryCombustionCarbonizationCO2 sequestrationCoalbed methaneCombustionMacerals in reflected white lightCoal geologyCoal geologyCoalbed methaneCoalbed methaneCoalbed methaneMacerals in reflected white lightChemistry of coal maceralsCoal geologyCoal geologyCombustionSuppressed reflectanceCoalbed methaneOil shaleOil shaleCoalbed methaneCoalbed methaneCoal as oil source rockCarbonizationWeathering and oxidationVisual kerogen analysisQuantitative fluorescenceVisual kerogen analysisCombustionCombustionCoal as oil source rockCoal geologyCoal geologyCoal geologyCoalbed methaneMacerals in reflected white lightOil shaleConversion (liquefaction and gasification)

Conversion (liquefaction and gasification)Conversion (liquefaction and gasification)Conversion (liquefaction and gasification)Oil shaleOil shaleOil shaleCoalbed-methane associated waterCoal as oil source rockCoal as oil source rockRock-Eval pyrolysisCoal as oil source rockCoalbed-methane associated waterOil shaleCoalbed methaneCoal geologyCoalbed methaneOil shaleCombustionCoalbed methaneCoalbed methaneCoal geologyConversion (liquefaction and gasification)Coalbed methaneOil shaleCoalbed methaneCoalbed methaneCoalbed methaneCO2 sequestrationCoalbed methaneCoal geologyCoal chemistryMinerals in coalMacerals in reflected white lightCoal explorationCoal geologySamplingCoal geologyGeneral references Fluorescence microscopyCoal geologyCoal geology

Macerals in reflected white lightMinerals in coalCoal geologyCoal geologyCoal geologyCoal geologyCoalbed methaneCoalbed methaneMinerals in coalCoal chemistryCoal chemistryCoal chemistryMinerals in coalCoal chemistryCombustionMinerals in coalMinerals in coalCoalbed methaneMinerals in coalCoal chemistryCoal chemistryCoal chemistryMinerals in coalCoalbed methaneCoal geologyCoal chemistryCoal chemistryMinerals in coalCoal chemistryQuantitative fluorescenceCoal geologyCoal as oil source rockConversion (liquefaction and gasification)Minerals in coalMacerals in reflected white lightCoal chemistryCoalbed methaneCoal explorationCoal geologyCoal geologyCoal geology

Coal geologyMacerals in reflected white lightCoal geologyChemistry of coal maceralsMacerals in reflected white lightCoal explorationCoal geologyGeneral references Vitrinite relectance analysisCoal chemistryCO2 sequestrationConversion (liquefaction and gasification)Oil shaleOil shaleChemistry of coal maceralsMacerals in reflected white lightChemistry of coal maceralsMacerals in reflected white lightCombustionVisual kerogen analysisCoalbed methaneCO2 sequestrationFluorescence microscopyQuantitative fluorescenceSamplingMacerals in reflected white lightMacerals in reflected white lightCO2 sequestrationCoalbed methaneCoal geologyVisual kerogen analysisMacerals in reflected white lightQuantitative fluorescenceVisual kerogen analysisQuantitative fluorescenceSolid hydrocarbonsFluorescence microscopyVisual kerogen analysisVisual kerogen analysisFluorescence microscopyQuantitative fluorescence

Macerals in reflected white lightQuantitative fluorescenceVisual kerogen analysisCoal as oil source rockVitrinite reflectanceQuantitative fluorescenceCoalbed methaneVisual kerogen analysisCoal geologyCoalbed methaneCoalbed methaneCoal chemistryMacerals in reflected white lightCoal chemistryVitrinite reflectanceCoalbed methaneCoalbed methaneCoalbed methaneCO2 sequestrationCoalbed methaneCarbonizationConversion (liquefaction and gasification)Conversion (liquefaction and gasification)Quantitative fluorescenceCombustionCarbonizationConversion (liquefaction and gasification)Coalbed methaneCombustionConversion (liquefaction and gasification)Coalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCO2 sequestrationVitrinite reflectanceCombustionConversion (liquefaction and gasification)Coal chemistry

Coalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoal chemistryVitrinite reflectanceMacerals in reflected white lightMacerals in reflected white lightCoal ballsCoalbed methaneCoal chemistryCoal as oil source rockFluorescence microscopyQuantitative fluorescenceCoal geologyCoal geologyCoal geologyCoal geologyCoal geologyCombustionCombustionCombustionCombustionCombustionCombustionConversion (liquefaction and gasification)Coalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneMinerals in coalCoal geologyCoalbed methaneVitrinite reflectanceCombustionCoalbed methaneCoal geology

Coal geologyCoal geologyCoal geologyCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneMacerals in reflected white lightSuppressed reflectanceCoal geologyCoal chemistryMacerals in reflected white lightMinerals in coalCombustionCarbonizationGeneral references General references Macerals in reflected white lightGeneral references Macerals in reflected white lightCombustionSuppressed reflectanceCoal explorationOil shaleZooclast reflectanceSolid hydrocarbonsCoal geologyVitrinite reflectanceVitrinite reflectanceCoal chemistryVitrinite reflectanceVitrinite reflectanceRock-Eval pyrolysisVitrinite reflectanceCoal as oil source rockCoal chemistryRock-Eval pyrolysisCoal chemistryVitrinite reflectanceOil shale

CombustionCoal chemistryRock-Eval pyrolysisMacerals in reflected white lightMacerals in reflected white lightCoal as oil source rockCoal chemistryWeathering and oxidationCO2 sequestrationCoal geologyMinerals in coalCoal explorationCoal chemistryVisual kerogen analysisVitrinite reflectanceCO2 sequestrationCoalbed methaneCoalbed methaneCoal chemistryCoal chemistryCoal chemistryMinerals in coalCoal chemistryCoal chemistryCoal chemistryCombustionWeathering and oxidationCombustionSamplingCO2 sequestrationCO2 sequestrationCoal geologyVitrinite reflectanceCO2 sequestrationCoal as oil source rockCoal as oil source rockMinerals in coalCoal geologyCoal as oil source rockRock-Eval pyrolysisCoal as oil source rock

Coal as oil source rockSuppressed reflectanceZooclast reflectanceMacerals in reflected white lightCO2 sequestrationCoalbed methaneCombustionSolid hydrocarbonsSolid hydrocarbonsCoalbed methaneCoalbed methaneCarbonizationConversion (liquefaction and gasification)Quantitative fluorescenceCO2 sequestrationCoal geologyCoalbed methaneCoalbed methaneCoalbed methaneConversion (liquefaction and gasification)Coalbed methaneOil shaleCoalbed methaneCombustionMacerals in reflected white lightMacerals in reflected white lightCombustionCoal chemistryCarbonizationMacerals in reflected white lightMacerals in reflected white lightSuppressed reflectanceVitrinite reflectanceCoal geologyMacerals in reflected white lightSuppressed reflectanceVitrinite reflectanceMacerals in reflected white lightMacerals in reflected white lightMacerals in reflected white lightGeneral references

Macerals in reflected white lightRock-Eval pyrolysisCoal geologyVitrinite reflectanceVitrinite relectance analysisCarbonizationCoal geologyCoal as oil source rockMacerals in reflected white lightCoal ballsCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoal as oil source rockVisual kerogen analysisQuantitative fluorescenceMacerals in reflected white lightVisual kerogen analysisFluorescence microscopyZooclast reflectanceFluorescence microscopyVisual kerogen analysisVisual kerogen analysisZooclast reflectanceVitrinite relectance analysisSuppressed reflectanceVitrinite relectance analysisCoal geologyCoal geologyCoal geologyCoal as oil source rockQuantitative fluorescenceRock-Eval pyrolysisVisual kerogen analysisVisual kerogen analysisFluorescence microscopyZooclast reflectanceVitrinite reflectance

Zooclast reflectanceCoalbed methaneCoalbed methaneCoalbed methaneCoal explorationCoal explorationOil shaleCoal geologyCoal chemistryCoalbed methaneCoal mine methaneCoalbed methaneCoalbed methaneCoal mine methaneCoalbed methaneCoal geologyMacerals in reflected white lightCoal geologyMacerals in reflected white lightCoal geologyMacerals in reflected white lightCoal geologyMacerals in reflected white lightCoal geologyMacerals in reflected white lightCoal geologyMacerals in reflected white lightCoal geologyCoal geologyMacerals in reflected white lightMacerals in reflected white lightCoal geologyCoal geologyMacerals in reflected white lightCoal chemistryCoalbed methaneCoal as oil source rockCombustionCombustionCombustionCarbonization

CombustionMacerals in reflected white lightVitrinite reflectanceCoal chemistryCoalbed methaneCoal chemistryCoalbed methaneGeneral references Coal explorationCoal geologyCoal geologyConversion (liquefaction and gasification)Coal geologyGeneral references Coal geologyGeneral references Coal mine methaneCoalbed methaneCoal explorationSamplingOil shaleCoalbed methaneVisual kerogen analysisMacerals in reflected white lightCoal geologyCarbonizationCarbonizationVitrinite reflectanceCarbonizationCarbonizationCoal as oil source rockCoal as oil source rockCoal as oil source rockSolid hydrocarbonsVisual kerogen analysisVisual kerogen analysisKerogen isolationQuantitative fluorescenceQuantitative fluorescenceCoal chemistryVisual kerogen analysis

Coalbed methaneVisual kerogen analysisQuantitative fluorescenceCoal geologyCoalbed methaneMacerals in reflected white lightVitrinite reflectanceVitrinite reflectanceMacerals in reflected white lightVitrinite reflectanceVitrinite reflectanceCoalbed methaneVitrinite reflectanceVitrinite reflectanceQuantitative fluorescenceVitrinite reflectanceVitrinite reflectanceCoalbed methaneMacerals in reflected white lightGeneral references Visual kerogen analysisCoal geologyVisual kerogen analysisVisual kerogen analysisVitrinite relectance analysisCoal as oil source rockRock-Eval pyrolysisCoal chemistryVitrinite reflectanceCoal mine methaneCombustionConversion (liquefaction and gasification)Coal chemistryCoal chemistryCoal mine methaneCoalbed methaneSuppressed reflectanceCombustionCoal chemistryVitrinite reflectanceVitrinite reflectance

Coal geologyMacerals in reflected white lightVisual kerogen analysisVisual kerogen analysisCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoal explorationCoal explorationCoal explorationCoal explorationCoal explorationZooclast reflectanceZooclast reflectanceCoal chemistryMacerals in reflected white lightCoal chemistryMacerals in reflected white lightCoal geologyCoalbed-methane associated waterSolid hydrocarbonsCoalbed methaneCoal explorationCombustionMacerals in reflected white lightSuppressed reflectanceCombustionCO2 sequestrationCoal explorationCoal chemistryCoal geologyCarbonizationCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoal geologyVisual kerogen analysis

Visual kerogen analysisVisual kerogen analysisVisual kerogen analysisVisual kerogen analysisGeneral references Visual kerogen analysisRock-Eval pyrolysisCO2 sequestrationCoalbed methaneOil shaleOil shaleOil shaleOil shaleOil shaleSamplingCoalbed methaneMacerals in reflected white lightQuantitative fluorescenceSuppressed reflectanceCoalbed methaneCoalbed methaneCombustionCO2 sequestrationMacerals in reflected white lightCombustionMinerals in coalMinerals in coalCoal chemistryCoal geologyCoal chemistryOil shaleCoal explorationOil shaleCO2 sequestrationGeneral references Coal as oil source rockCoal chemistryVitrinite reflectanceCombustionMacerals in reflected white lightCombustion

CombustionCombustionVitrinite reflectanceGeneral references Macerals in reflected white lightCarbonizationWeathering and oxidationCarbonizationCarbonizationCarbonizationCarbonizationCombustionCoal chemistryMinerals in coalCoal chemistryCO2 sequestrationCoalbed methaneCO2 sequestrationCO2 sequestrationCoal chemistryMacerals in reflected white lightVisual kerogen analysisMacerals in reflected white lightCoal geologyCoal chemistryCoal chemistryCoal geologyCO2 sequestrationCO2 sequestrationCombustionConversion (liquefaction and gasification)Quantitative fluorescenceQuantitative fluorescenceQuantitative fluorescenceQuantitative fluorescenceQuantitative fluorescenceQuantitative fluorescenceQuantitative fluorescenceSolid hydrocarbonsVisual kerogen analysisQuantitative fluorescence

Solid hydrocarbonsVisual kerogen analysisVitrinite reflectanceVitrinite reflectanceCoalbed methaneVisual kerogen analysisCoal as oil source rockCoal chemistryWeathering and oxidationCoal chemistryCoal explorationCoal geologyCoal chemistryCoal chemistryCoal chemistryMacerals in reflected white lightConversion (liquefaction and gasification)Macerals in reflected white lightMacerals in reflected white lightMacerals in reflected white lightConversion (liquefaction and gasification)CO2 sequestrationCoalbed methaneCoalbed-methane associated waterOil shaleOil shaleOil shaleOil shaleOil shaleKerogen isolationVisual kerogen analysisMinerals in coalCarbonizationCoal geologyCarbonizationCarbonizationCombustionCO2 sequestrationZooclast reflectanceCoal chemistryMinerals in coal

Coal chemistryMinerals in coalMinerals in coalCombustionCombustionCoal chemistryMinerals in coalCoal chemistryCoal chemistryMinerals in coalOil shaleOil shaleCoalbed-methane associated waterCombustionMinerals in coalSuppressed reflectanceSuppressed reflectanceVitrinite reflectanceVitrinite reflectanceCoal geologySuppressed reflectanceQuantitative fluorescenceVitrinite reflectanceVitrinite reflectanceVisual kerogen analysisVisual kerogen analysisVitrinite reflectanceSolid hydrocarbonsSolid hydrocarbonsVitrinite reflectanceCoal chemistryCoal chemistryCombustionCoal chemistryCoalbed methaneKerogen isolationCO2 sequestrationCO2 sequestrationCoal chemistryCO2 sequestrationCombustion

CombustionCombustionZooclast reflectanceMineral matrix effectsVitrinite reflectanceCO2 sequestrationQuantitative fluorescenceCoal as oil source rockCoalbed methaneCombustionCoal explorationCoal chemistryMinerals in coalCoal as oil source rockCoal chemistryCarbonizationWeathering and oxidationCoal geologyCoalbed methaneCoalbed methaneCoalbed methaneWeathering and oxidationWeathering and oxidationCoal chemistryCoal chemistryConversion (liquefaction and gasification)Conversion (liquefaction and gasification)Coal geologyCoal chemistryCoal chemistryCoalbed methaneCO2 sequestrationCarbonizationChemistry of coal maceralsMacerals in reflected white lightCoalbed methaneCarbonizationCarbonizationCO2 sequestrationSolid hydrocarbonsFluorescence microscopy

Vitrinite reflectanceCoalbed methaneCO2 sequestrationCoalbed methaneCO2 sequestrationCoalbed methaneCoalbed methaneWeathering and oxidationWeathering and oxidationCoal geologyCoal chemistryCoalbed methaneCoalbed methaneCoalbed methaneOil shaleCoal chemistryCoalbed methaneCO2 sequestrationCoalbed methaneMacerals in reflected white lightMacerals in reflected white lightConversion (liquefaction and gasification)Coalbed methaneCombustionCoal chemistryCoal chemistryCoal chemistryMinerals in coalCombustionMinerals in coalCoal chemistryCoal chemistryCoal chemistryMinerals in coalCoal chemistryMinerals in coalCoal chemistryCoalbed methaneCoal chemistryCoal chemistryCoal exploration

Coal geologyMacerals in reflected white lightCoal geologyCoal geologyCoal geologyCoal geologyCoal geologyCoal geologyCoal geologyCoal geologyCoal geologyCoal geologyVitrinite reflectanceSuppressed reflectanceMinerals in coalMinerals in coalCoal chemistryMinerals in coalMinerals in coalMinerals in coalMinerals in coalCoalbed methaneMinerals in coalCoal chemistryCoal chemistryMinerals in coalCoal chemistryMinerals in coalMinerals in coalCoal chemistryCombustionCoal chemistryMinerals in coalGeneral references Coal geologyMinerals in coalCoal chemistryMinerals in coalCoal chemistryMacerals in reflected white lightVitrinite reflectance

Chemistry of coal maceralsCoal chemistryMacerals in reflected white lightMinerals in coalSuppressed reflectanceVitrinite reflectanceCoal chemistryMacerals in reflected white lightMinerals in coalCoal geologyMacerals in reflected white lightCoal geologyCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneOil shaleOil shaleZooclast reflectanceCoal chemistryCoal explorationSolid hydrocarbonsCO2 sequestrationCoalbed methaneConversion (liquefaction and gasification)Coal explorationCoal explorationCO2 sequestrationCoalbed methaneWeathering and oxidationCoalbed methaneCoalbed methaneCoalbed methaneCoal as oil source rockCO2 sequestrationCoalbed methaneCoal chemistry

Macerals in reflected white lightCoal geologyCO2 sequestrationCoalbed methaneCoalbed methaneOil shaleCoalbed-methane associated waterCoal geologyCoal geologyCoal geologyCoal geologyCoal geologyCoal geologyCO2 sequestrationConversion (liquefaction and gasification)Coalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoal as oil source rockCoal as oil source rockMineral matrix effectsMineral matrix effectsVitrinite reflectanceSuppressed reflectanceCO2 sequestrationCoalbed methaneCO2 sequestrationCoalbed methaneSequestration in shalesCoal chemistryConversion (liquefaction and gasification)CombustionCoal chemistryCO2 sequestrationSolid hydrocarbonsCoal geologyCoal geologyCoalbed methaneCoalbed methane

Coal geologyMinerals in coalKerogen isolationRock-Eval pyrolysisCO2 sequestrationCO2 sequestrationCoalbed methaneCoal chemistryMacerals in reflected white lightMacerals in reflected white lightCoal geologyMacerals in reflected white lightCoal geologyCoal geologyCoal geologyMacerals in reflected white lightCO2 sequestrationSolid hydrocarbonsCoal geologyConversion (liquefaction and gasification)Conversion (liquefaction and gasification)Vitrinite reflectanceCoal mine methaneVisual kerogen analysisCoalbed methaneCoal chemistryCoal geologyMinerals in coalMinerals in coalCO2 sequestrationCoalbed methaneCoal geologyCO2 sequestrationCoal chemistryCombustionConversion (liquefaction and gasification)Macerals in reflected white lightWeathering and oxidationRock-Eval pyrolysisCarbonizationCoal as oil source rock

Suppressed reflectanceQuantitative fluorescenceSuppressed reflectanceVitrinite reflectanceWeathering and oxidationQuantitative fluorescenceSuppressed reflectanceSuppressed reflectanceVitrinite reflectanceQuantitative fluorescenceSuppressed reflectanceVitrinite reflectanceQuantitative fluorescenceSuppressed reflectanceVitrinite reflectanceVitrinite reflectanceVitrinite reflectanceCoal geologyCarbonizationCoalbed methaneCoal chemistryCoal ballsCoal geologyCoal ballsCoal mine methaneCombustionConversion (liquefaction and gasification)Solid hydrocarbonsCoal geologyCoal chemistryCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneOil shaleCoalbed methaneCoalbed methaneCoalbed methane

Oil shaleCoalbed methaneCoalbed methaneCO2 sequestrationCoalbed methaneCoalbed methaneZooclast reflectanceCoal geologyVisual kerogen analysisOil shaleCO2 sequestrationCarbonizationQuantitative fluorescenceCoalbed-methane associated waterCO2 sequestrationSolid hydrocarbonsSolid hydrocarbonsCO2 sequestrationCoalbed methaneChemistry of coal maceralsCoal geologyCoal geologyMacerals in reflected white lightOil shaleOil shaleOil shaleCombustionCoal ballsCoal chemistryMacerals in reflected white lightCoal geologyCoal geologyCoalbed methaneCoal mine methaneOil shaleCoalbed methaneCoalbed methaneMacerals in reflected white lightCoal chemistryCombustionCombustion

CO2 sequestrationCoalbed methaneKerogen isolationCoal explorationCombustionCO2 sequestrationCoal chemistryCoalbed methaneCoalbed methaneCoal geologyCoal chemistryWeathering and oxidationCO2 sequestrationCO2 sequestrationCoal geologyCoal geologyMinerals in coalCoalbed methaneCombustionZooclast reflectanceCoalbed methaneCoal chemistryFluorescence microscopyBitumen reflectanceSolid hydrocarbonsBitumen reflectanceVitrinite reflectanceZooclast reflectanceZooclast reflectanceZooclast reflectanceBitumen reflectanceZooclast reflectanceCoalbed methaneCombustionOil shaleVisual kerogen analysisCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methane

CO2 sequestrationCO2 sequestrationCO2 sequestrationCombustionCoal chemistryCoal mine methaneCoal as oil source rockCoalbed methaneCoal as oil source rockCoalbed methaneCoalbed methaneVitrinite reflectanceCO2 sequestrationConversion (liquefaction and gasification)Coal chemistryVitrinite reflectanceZooclast reflectanceCO2 sequestrationCoal chemistryCoalbed methaneCoal mine methaneCoalbed methaneCoalbed methaneGeneral references Coal as oil source rockMacerals in reflected white lightCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCombustionSolid hydrocarbonsConversion (liquefaction and gasification)Coalbed methaneCoalbed methaneOil shaleOil shaleFluorescence microscopyOil shale

Oil shaleCoalbed-methane associated waterCoalbed methaneCO2 sequestrationCoalbed methaneCombustionCoal chemistryMinerals in coalMinerals in coalCoal chemistryMinerals in coalCoalbed methaneCoalbed methaneCoalbed methaneCO2 sequestrationConversion (liquefaction and gasification)CO2 sequestrationCoalbed methaneCO2 sequestrationCoalbed methaneCO2 sequestrationCoalbed methaneCO2 sequestrationMacerals in reflected white lightCombustionCoal geologyCoal chemistryCoal chemistryCoal chemistryCoal chemistryCoal chemistryCoal chemistryCoal chemistryMinerals in coalVitrinite reflectanceSolid hydrocarbonsCoal chemistrySolid hydrocarbonsCoal chemistryCoalbed methaneCoalbed methane

Coal geologyCoal geologyCO2 sequestrationCoalbed methaneCO2 sequestrationCoal mine methaneCoal geologyCoal geologyCoal geologyCarbonizationVitrinite relectance analysisMinerals in coalSuppressed reflectanceVitrinite reflectanceSuppressed reflectanceCoalbed methaneCombustionCoalbed methaneCoal chemistryMinerals in coalCombustionOil shaleCoal as oil source rockCO2 sequestrationCombustionWeathering and oxidationMinerals in coalMinerals in coalMinerals in coalCoal chemistryCombustionMinerals in coalCoal chemistryCombustionOil shaleCoal chemistryCoal chemistryCoal chemistryCoalbed methaneCO2 sequestrationCombustion

Minerals in coalBitumen reflectanceSolid hydrocarbonsMinerals in coalCoalbed methaneCoalbed-methane associated waterCoalbed methaneCoal as oil source rockCO2 sequestrationCO2 sequestrationCO2 sequestrationCoal chemistryMinerals in coalMinerals in coalMinerals in coalCoal chemistryCombustionCoalbed methaneCarbonizationVisual kerogen analysisCoal chemistryMacerals in reflected white lightMacerals in reflected white lightCoal geologyMinerals in coalSuppressed reflectanceVitrinite reflectanceCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCoalbed methaneCombustion

Abdel-Baset, M.B., R.F. Yarzab, and P.H. Given, 1978, Dependence of coal liquefaction behaviour on coal characteristics. 3. Statistical correlations of conversion in coal-tetralin interactions: Fuel, v. 57, p. 89-94.Abernethy, R.F., and F.H. Gibson, 1963, Rare elements in coal: U.S. Bureau of Mines Information Circular 8163, 69 p.Abraham, H., 1960, Asphalts and allied substances (sixth edition, 5 volumes): New York, Van Nostrand Company, Inc.Abraham, K.S., 2006, Coalbed methane activity expands further in North America: World Oil, v. 226, no. 8, p. 61-62.Abramski, C., M.-Th. Mackowsky, W. Mantel, and E. Stach, 1951, Atlas für angewandte steinkohlen-petrographie: Verlag Glückauf G.M.B.H., Essen, 329 p.Abu Hamad, A.M.B., A. Jasper, and D. Uhl, 2012, The record of Triassic charcoal and other evidence for palaeo-wildfires: Signal for atmospheric oxygen levels, taphonomic biases or lack of fuel?: International Journal of Coal Geology, v. 96-97, p. 60-71.Adams, D.M.B., and I.M. Smith, 1995, Sulphates, climate, and coal: Perspectives series no. IEAPER/16, 30 p. (SO2 emissions)Adams, E.E., and K. Caldeira, 2008, Ocean storage of CO2: Elements, v. 4, p. 319-324.

Adanez, J., J.C. Abbanades, and L.F. de Diego, 1994, Determination of coal combustion reactivities by burnout-time measurements in a batch fluidized bed: Fuel, v. 73, p. 287.Adeboye, O.O., and R.M. Bustin, 2013, Variation of gas flow properties in coal with probe gas, composition and fabric: Examples from western Canadian sedimentary basin: International Journal of Coal Geology, v. 108, p. 47-52.

Afzal, P., S.H. Alhoseini, B. Tokhmechi, D.K. Ahangaran, A.B. Yasrebi, N. Madani, and A. Wetherelt, 2014, Outlining of high quality coking coal by concentration-volume fractal model and turning bands simulation in East-Parvadeh coal deposit, central Iran: International Journal of Coal Geology, v. 127, p. 88-99.Agapito, J.F.T., ed., 1985, Western synfuels symposium proceedings: Colorado School of Mines Press, 130 p.Aguilera, R.F., R.D. Ripple, and R. Aguilera, 2014, Link between endowments, economics and environment in conventional and unconventional gas reservoirs: Fuel, v. 126, p. 224-238.Ahmed, M., and A. Rahim, 1996, Abundance of sulfur in Eocene coal beds from Bapung, northeast India: International Journal of Coal Geology, v. 30, p. 315-318.Ahmed, M., and J.W. Smith, 2001, Biogenic methane generation in the degradation of eastern Australian Permian coals: Organic Geochemistry, v. 32, p. 809-816.Ahmed, M., H. Volk, S.C. George, M. Faiz, and L. Stalker, 2009, Generation and expulsion of oils from Permian coals of the Sydney Basin, Australia: Organic Geochemistry, v. 40, p. 810-831.Ahmed, M., J.W. Smith, and S.C. George, 1999, Effects of biodegradation on Australian Permian coals: Organic Geochemistry, v. 30, p. 1311-1322.Aizenshtat, Z., I. Miloslavski, and E. Tannenbaum, 1986, Thermal behavior of immature asphalts and related kerogens: Organic Geochemistry, v. 10, p. 537-546.Akande, S.O., I.B. Ogunmoyero, H.I. Petersen, and H.P. Nytoft, 2007, Source rock evaluation of coals from the Lower Maastrichtian Mamu Formation, SE Nigeria: Journal of Petroleum Geology, v. 30, p. 303-324.Akande, S.O., O.J. Ojo, B.D. Erdtmann, and M. Hetenyi, 1998, Paleoenvironments, source rock potential and thermal maturity of the Upper Benue rift basins, Nigeria: implications for hydrocarbon exploration: Organic Geochemistry, v. 29, p. 531-542.Akar, G., S. Sen, H. Yilmaz, V. Arslan, and U. Ipekoglu, 2013, Characterization of ash deposits from the boiler of Yenikoy coal-fired power plant, Turkey: International Journal of Coal Geology, v. 105, p. 85-90.Akinlua, A., T.R. Ajayi, D.M. Jarvie, and B.B. Adeleke, 2005, A re-appraisal of the application of Rock-Eval pyrolysis to source rock studies in the Niger Delta: Journal of Petroleum Geology, v. 28, p. 39-47.

Alexeev, A.D., E.P. Feldman, and T.A. Vasilenko, 2007, Methane desorption from a coal-bed: Fuel, v. 86, p. 2574-2580.Alexeev, A.D., E.V. Ulyanova, G.P. Starikov, and N.N. Kovriga, 2004, Latent methane in fossil coals: Fuel, v. 83, p. 1407-1411.Alias, F.L., W.H. Abdullah, M.H. Hakimi, M.H. Azhar, and R.L. Kugler, 2012, Organic geochemical characteristics and depositional environment of the Tertiary Tanjong Formation coals in the Pinangah area, onshore Sabah, Malaysia: International Journal of Coal Geology, v. 104, p. 9-21.

Allen, R.M., and J.B. Vander Sande, 1984, Analysis of submicron mineral matter in coal via scanning-transmission electron microscopy: Fuel, v. 63, p. 24-29.Allix, P., A. Burnham, T. Fowler, M. Herron, R. Kleinberg, and B. Symington, 2010, Coaxing oil from shale: Oilfield Review, v. 22, no. 4, p. 4-15.Al-Mahmoud, M.J., S. İnan, and A.A. Al-Duaiji, 2014, Coal occurrence in the Jurassic Dhruma Formation in Saudi Arabia: Inferences on it gas and surface mining potential: International Journal of Coal Geology, v. 124, p. 5-10.

Ammosov, I.I., 1981, Petrographic features of solid organic matter as indicators of paleotemperatures and oil potential, in H.D. Hedberg and J.F. Mason, eds., Petroleum geochemistry, genesis, and migration: International Geology Review, 1968-1981: American Geological Institute, Reprint Series 6, p. 238-248.

Adams, M.A., 1984, Geologic overview, coal resources, and potential methane recovery from coalbeds of the central Appalachian basin—Maryland, West Virginia, Virginia, Kentucky, and Tennessee, in C.T. Rightmire, G.E. Eddy, and J.N. Kirr, eds., Coalbed methane resources of the United States: AAPG Studies in Geology 17, p. 45-71.Adams, M.A., and J.N. Kirr, 1984, Geologic overview, coal deposits, and potential for methane recovery from coalbeds of the Uinta Basin—Utah and Colorado, in C.T. Rightmire, G.E. Eddy, and J.N. Kirr, eds., Coalbed methane resources of the United States: AAPG Studies in Geology 17, p. 253-269.Adams, M.A., G.E. Eddy, J.L. Hewitt, J.N. Kirr, and C.T. Rightmire, 1984, Geologic overview, coal resources, and potential methane recovery from coalbeds of the northern Appalachian coal basin—Pennsylvania, Ohio, Maryland, West Virginia, and Kentucky, in C.T. Rightmire, G.E. Eddy, and J.N. Kirr, eds., Coalbed methane resources of the United States: AAPG Studies in Geology 17, p. 15-43.

Adkins-Heljeson, D., L.L. Brady, T.A. Carr, and J.P. Penka, 2004, Summary of Kansas coalbed methane wells and production history: Kansas Geological Survey Open-file Report 2004-37. (http://www.kgs.ku.edu/PRS/publication/2004/OFR04_37/index.html).Advanced Resources International, 2003, Directional drilling technology: U.S. Environmental Agency, Surface Drilling Series, 11 p. http://www.epa.gov/coalbed/pdf/dir-drilling.pdfAffolter, R.H., and G.D. Stricker, 1990, Paleolatitude—a primary control on the sulfur content of United States coal (abstract), in L.M.H. Carter, ed., USGS research on energy resources—1990 program and abstracts: U.S. Geological Survey Circular 1060, p. 1.

Alain, A.K., and G.M. Denes, 1992, Cavity stress relief method to stimulate demethanation boreholes, in Coalbed methane: Society of Petroleum Engineers, Reprint Series 35, p. 131-138.Aleksic, B.R., M.D. Ercegovac, O.G. Cvetkovic, and others, 1997, Conversion of low rank coal into liquid fuels by direct hydrogenation, in R. Gayer and J. Pesek, eds., European coal geology and technology: London, Geological Society Special Publication 125, p. 357-363.

ALL Consulting, 2003, Handbook on coal bed methane produced water: management and beneficial use alternatives: Coal bed methane resources and produced water management, U.S. Department of Energy, Office of Fossil Energy, National Energy Technology Laboratory, CD. (http://www.all-llc.com/CBM/BU/index.htm)Allan, J., and S.R. Larter, 1983, Aromatic structures in coal maceral extracts and kerogens, in M. Bjoroy and others, eds., Advances in organic geochemistry 1981: New York, John Wiley & Sons Ltd., p. 534-545.Allan, J., M. Bjoroy, and A.G. Douglas, 1980, A geochemical study of the exinite group maceral alginate, selected from three Permo-Carboniferous torbanites, in A.G. Douglas and J.R. Maxwell, eds., Advances in Organic Geochemistry 1979: London, Pergamon Press, p. 599-618.Allan, J., M. Bjoroy, and A.G. Douglas, 1980, A geochemical study of the exinite group maceral alginate, selected from three Permo-Carboniferous torbanites, in A.G. Douglas and J.R. Maxwell, eds., Advances in Organic Geochemistry 1979: New York, Pergamon Press, Physics and Chemistry of the Earth, v. 12, p. 599-618.

Alonso, M.J.G., A.G. Borrego, D. Alvarez, and R. Menendez, 2001, A reactivity study of chars obtained at different temperatures in relation to their petrographic characteristics: Fuel Processing Technology, v. 69, p. 257-272.Alpern, B., 1970, Classification petrographie des constituents organiques fossiles des roches sedimentaires: Revue de l'Institut Francais du Petrole, v. 25, p. 1233-1267.

Alpern, B., 1981, Les schistes bitumineux: constitution, reserves, valorisation: Bulletin des Centres de Recherches Exploration-Production, Elf Aquitaine, v. 5, p. 319-352.Alpern, B., 1981, Pour une classification synthetique universelle des combustibles solides: Bulletin des Centres de Recherches Exploration-Production, Elf Aquitaine, v. 5, p. 271-290.Alpern, B., and D. Cheymol, 1978, Reflectance et fluorescence des organoclastes du Toarcien du bassin de Paris en fonction de la profondeur et de la temperature: Revue de l'Institut Francais du Petrole, v. 33, p. 515-535.Alpern, B., and M.J. Lemos de Sousa, 2002, Documented international enquiry on solid sedimentary fossil fuels; coal: definitions, classifications, reserves-resources, and energy potential: International Journal of Coal Geology, v. 50, p. 3-41.Alpern, B., and M.J. Lemos de Sousa, 2002, Documented international enquiry on solid sedimentary fossil fuels; coal: definitions, classifications, reserves-resources, and energy potential: International Journal of Coal Geology, v. 50, p. 3-41.

Alpern, B., M.J. Lemos de Sousa, and D. Flores, 1989, A progress report on the Alpern Coal Classification: International Journal of Coal Geology, v. 13, p. 1-19.Alpern, B., M.J. Lemos de Sousa, H.J. Pinheiro, and X. Zhu, 1992, Optical morphology of hydrocarbons and oil progenitors in sedimentary rocks - relations with geochemical parameters: Publ. Mus. Labor. Miner. Geol. Fac. Cienc. Porto N.S., 3, p. 1-21.Alpern, B., M.J. Lemos De Sousa, H.J. Pinheiro, and X. Zhu, 1993, Detection and evaluation of hydrocarbons in source rocks by fluorescence microscopy: Organic Geochemistry, v. 20, p. 789-795.

Alqudah, M., M.A. Hussein, S. van den Boorn, V.M. Giraldo, S. Kolonic, O.G. Podlaha, and J. Mutterlose, 2014, Eocene oil shales from Jordan — Paleoenvironmental implications from reworked microfossils: Marine and Petroleum Geology, v. 52, p. 93-106.Alsaab, D., I. Suarez-Ruiz, M. Elie, A. Izart, and L. Martinez, 2007, Comparision of generative capacities for bitumen and gas between Carboniferous coals from Donets Basin (Ukraine) and a Cretaceous coal from Sabinas-Piedras Negras Basin (Mexico) during artificial maturation in confined pyrolysis system: International Journal of Coal Geology, v. 71, p. 85-102.Alsaab, D., M. Elie, A. Izart, R.F. Sachsenhofer, and V.A. Privalov, 2008, Predicting methane accumulations generated from humic Carboniferous coals in the Donbas fold belt (Ukraine): AAPG Bulletin, v. 92, p. 1029-1053.Alsaab, D., M. Elie, A. Izart, R.F. Sachsenhofer, V.A. Privalov, I. Suarez-Ruiz, and A. Martinez, 2011, Erratum to "Comparison of hydrocarbon gases (C1-C5) production from Carboniferous Donets (Ukraine) and Cretaceous Sabinas (Mexico) coals": International Journal of Coal Geology, v. 86, p. 295.Alsaab, D., M. Elie, A. Izart, R.F. Sachsenhofer, V.A. Privalov, I. Suarez-Ruiz, and L. Martinez, 2008, Comparison of hydrocarbon gases (C1-C5) production from Carboniferous Donets (Ukraine) and Cretaceous Sabinas (Mexico) coals: International Journal of Coal Geology, v. 74, p. 154-162.Alsaab, D., M. Elie, A. Izart, R.F. Sachsenhofer, V.A. Privalov, I. Suarez-Ruiz, L. Martinez, and E.A. Panova, 2009, Distribution of thermogenic methane in Carboniferous coal seams of the Donets Basin (Ukraine): "Applications to exploitation of methane and forecast of mining hazards": International Journal of Coal Geology, v. 78, p. 27-37.Altschuler, Z.S., M.M. Schnepfe, C.C. Silber, and F.O. Simon, 1983, Sulfur diagenesis in Everglades peat and origin of pyrite in coal: Science, v. 221, no. 4607, p. 221-227.

Alvarez, M.C., M.T. Dopico, and P.A. Amengual, 1994, A study of the correlation between ash content and natural radionuclide content in hard coals from northern Spain: Journal of Coal Quality, v. 13, no. 1, p. 10-12.Álvarez-Rodríguez, R., and C. Clemente-Jul, 2008, Hot gas desulphurization with dolomite sorbent in coal gasification: Fuel, v. 87, p. 3513-3521.

Ambrose, W.A., and W.B. Ayers, Jr., 2007, Geologic controls on transgressive-regressive cycles in the upper Pictured Cliffs Sandstone and coal geometry in the lower Fruitland Formation, northern San Juan Basin, New Mexico and Colorado: AAPG Bulletin, v. 91, p. 1099-1122.Ambrose, W.A., C. Breton, S.D. Hovorka, I.J. Duncan, G. Gülen, M.H. Holtz, and V. Núñez-López, 2011, Geologic and infrastructure factors for delineating areas for clean coal: examples in Texas, USA: Environmental Earth Sciences, v. 63, p. 513-532.Ambrose, W.A., C. Breton, V. Núñez-López, and G. Gülen, 2012, Geologic and economic criteria for siting clean-coal facilities in the Texas Gulf Coast, USA: Natural Resources Research, v. 21, p. 461-482.Ambrose, W.A., E.C. Potter, and R. Briceno, 2008, An "unconventional" future for natural gas in the United States: Geotimes, v. 53, no. 2, p. 37-41.Ambrose, W.A., S. Lakshminarasimhan, M.H. Holtz, V. Núñez-López, S.D. Hovorka, and I. Duncan, 2008, Geologic factors controlling CO2 storage capacity and permanence: case studies based on experience with heterogeneity in oil and gas reservoir applied to CO2 storage: Environmental Geology, v. 54, p. 1619-1633.Amer, M.W., M. Marshall, Y. Fei, W.R. Jackson, M.L. Gorbaty, P.J. Cassidy, and A.L. Chaffee, 2014, A comparison of the structure and reactivity of five Jordanian oil shales from different locations: Fuel, v. 119, p. 313-322.American Gilsonite Company, 1969, Gilsonite Guide Book: Salt Lake City, Utah, American Gilsonite Company, 22 p.American Gilsonite Company, 1979, Gilsonite: Salt Lake City, Utah, American Gilsonite Company, 16 p.American Oil & Gas Reporter, 2006, PAW grapples with coalbed gas water: American Oil & Gas Reporter, v. 49, no.8, p. 125-126.American Society for Testing and Materials (ASTM), 1994, Standard test method for microscopical determination of the reflectance of vitrinite in a polished specimen of coal: Annual book of ASTM standards: gaseous fuels; coal and coke, sec. 5, v. 5.05, D 2798-91, p. 280-283.

Amijaya, H., and R. Littke, 2005, Microfacies and depositional environment of Tertiary Tanjung Enim low rank coal, south Sumatra Basin, Indonesia: International Journal of Coal Geology, v. 61, p. 197-221.Amijaya, H., J. Schwarzbauer, and R. Littke, 2006, Organic geochemistry of the Lower Suban coal seam, South Sumatra Basin, Indonesia: palaeoecological and thermal metamorphism implications: Organic Geochemistry, v. 37, p. 261-279.Ammosov, I.I., 1968, Coal organic matter as a parameter for the degree of sedimentary rock lithification: Proceedings, 23rd International Geological Congress, Prague, Sec. 11, p. 23-30.Ammosov, I.I., 1979, Petrographic features of solid organic materials as indicators of paleotemperatures and oil potential: International Geology Review, v. 23, p. 406-416.Ammosov, I.I., 1981, Petrographic features of solid organic materials as indicators of paleotemperatures and oil potential: International Geology Review, v. 23, p. 406-416.

Alpern, B., 1980, Petrographie du kerogene, in B. Durand, ed., Kerogen - insoluble organic matter from sedimentary rocks: Paris, Editions Technip, p. 339-383.

Alpern, B., B. Durand, J. Espitalie, and B. Tissot, 1972, Localisation, caracterisation et classification petrographique des substances organiques sedimentaires fossiles, in H.R. v. Gaertner and H. Wehner, eds., Advances in organic geochemistry 1971: New York, Pergamon Press, p. 1-28.

Alpert, S.B., 1991, Clean coal technology and advanced coal-based power plants, in J.M. Hollander, ed., Annual Review of Energy and the Environment: Palo Alto, Annual Reviews Inc., Energy and the Environment, v. 16, p. 1-23.

Alturki, Y.I.A., G. Eglinton, and C.T. Pillinger, 1972, The petroporphyrins of gilsonite, in H.R.V. Gaertner and H. Wehner, eds., Advances in Organic Geochemistry 1971: New York, Pergamon Press, p. 135-150.

Ambrose, W.A., and W.B. Ayers, Jr., 1991, Geologic controls on coalbed methane occurrence and producibility in the Fruitland Formation, Cedar Hill field and COAL site, San Juan Basin, Colorado and New Mexico, in S.D. Schwochow, D.K. Murray, and M.F. Fahy, eds., Coalbed methane of western North America: Denver, CO, Rocky Mountain Association of Geologists Guidebook, p. 227-240.

American Society for Testing and Materials (ASTM), 2011, Standard test method for microscopical determination of the reflectance of vitrinite dispersed in sedimentary rocks: West Conshohocken, PA, ASTM International, Annual book of ASTM standards: Petroleum products, lubricants, and fossil fuels; Gaseous fuels; coal and coke, sec. 5, v. 5.06, D7708-11, p. 823-830, doi: 10.1520/D7708-11, http://www.astm.org/Standards/D7708.htmAmerican Society for Testing and Materials (ASTM), 2014, Standard test method for microscopical determination of the reflectance of vitrinite dispersed in sedimentary rocks: West Conshohocken, PA, ASTM International, Annual book of ASTM standards: Petroleum products, lubricants, and fossil fuels; Gaseous fuels; coal and coke, sec. 5, v. 5.06, D7708-14, p. 823-830, doi: 10.1520/D7708-11, http://www.astm.org/Standards/D7708.htm

Ammosov, I.I., and I.V. Eremin, 1963, Fracturing in coal (translated from Russian): IZDAT Publishers, Office of Technical Services, Washington, D.C., 112 p. (cleat vs. rank)

Anderson, J., and 15 others, 2003, Producing natural gas from coal: Schlumberger, Oilfield Review, v. 15, no. 3, p. 8-31.Anderson, K.B., and J.C. Crelling, eds., 1995, Amber, resinite, and fossil resins: Washington, D.C., American Chemical Society Symposium Series 617, 297 p.Anderson, K.B., and R.B. Johns, 1986, Oxidation studies of Australian coals—I. Aliphatic and aromatic hydrocarbon centres of oxidative attack: Organic Geochemistry, v. 9, p. 219-224.Anderson, K.B., J.C. Crelling, F. Kenig, and W.W. Huggett, 2007, An unusual non-fluorescing algal kerogen from the Canadian Arctic: International Journal of Coal Geology, v. 69, p. 144-152.Anderson, K.B., J.C. Crelling, F. Kenig, and W.W. Huggett, 2007, An unusual non-fluorescing algal kerogen from the Canadian Arctic: International Journal of Coal Geology, v. 69, p. 144-152.Anderson, K.B., J.C. Crelling, F. Kenig, and W.W. Huggett, 2007, An unusual non-fluorescing algal kerogen from the Canadian Arctic: International Journal of Coal Geology, v. 69, p. 144-152.Anderson, K.B., R.E. Winans, and R.E. Botto, 1992, The nature and fate of natural resins in the geosphere—II. Identification, classification and nomenclature of resinites: Organic Geochemistry, v. 18, p. 829-841.Anderson, L.I., J.A. Dunlop, R.M.C. Eagar, C.A. Horrocks, and H.M. Wilson, 1999, Soft-bodies fossils from the roof shales of the Wigan Four Foot coal seam, Westhoughton, Lancashire, UK: Geological Magazine, v. 135, p. 321-329.

Anderson, T.F., M.E. Brownlee, and T.L. Phillips, 1980, A stable isotope study on the origin of permineralized peat zones in the Herrin coal: Journal of Geology, v. 88, p. 713-722.Andersson, Astrid, and others, 1985, The Scandinavian alum shales: Sveriges Geologiska Undersökning, Avhandlingar Och Uppsatser I A4, Ser. Ca, nr. 56, 50 p.Andrews, H.N., Jr., 1951, American coal-ball floras: Botanical Review, v. 17, p. 431-469.Andrews, H.N., Jr., and S.H. Mamay, 1952, A brief conspectus of American coal ball studies: Palaeobotanist, v. 1, p. 66-72.Andrews, R.D., B.J. Cardott, and T. Storm, 1998, The Hartshorne play in southeastern Oklahoma: regional and detailed sandstone reservoir analysis and coalbed-methane resources: Oklahoma Geological Survey Special Publication 98-7, 90 p.

Angelone, M., C. Gasparini, M. Guerra, S. Lombardi, L. Pizzino, F. Quattrocchi, E. Sacchi, and G.M. Zuppi, 2005, Fluid geochemistry of the Sardinian Rift-Campidiano Graben (Sardinia, Italy): fault segmentation, seismic quiescence of geochemically "active" faults, and new constraints for selection of CO2 storage sites: Applied Geochemistry, v. 20, p. 317-340.Anggara, F., K. Sasaki, S. Rodrigues, and Y. Sugai, 2014, The effect of megascopic texture on swelling of a low rank coal in supercritical carbon dioxide: International Journal of Coal Geology, v. 125, p. 45-56.Anna, L.O., 2003, Groundwater flow associated with coalbed gas production, Ferron Sandstone, east-central Utah: International Journal of Coal Geology, v. 56, p. 69-95.Anna, L.O., 2003, Groundwater flow associated with coalbed gas production, Ferron Sandstone, east-central Utah: International Journal of Coal Geology, v. 56, p. 69-95.Anonymous, 1993, Coal assessment for maximum combustion efficiency: Erdol und Kohle-Erdgas-Petrochemie, v. 46, no. 11, p. 404.Anonymous, 2005, Study assesses future for oil shales: American Oil & Gas Reporter, v. 48, no. 10, p. 171-172.Anonymous, 2006, Canadian CBM: hitting the target: An investor’s guide to coalbed methane, A supplement to Oil and Gas Investor, v. 26, no. 12, p. 26-27.Anonymous, 2006, Geo-modeling of thin-bed coal reservoirs: An investor’s guide to coalbed methane, A supplement to Oil and Gas Investor, v. 26, no. 12, p. 28.

Anonymous, 2009, NOSA provides facts about oil shale: American Oil & Gas Reporter, v. 52, no. 4, p. 175-176.Anonymous, 2009, Report estimates shale oil resource: American Oil & Gas Reporter, v. 52, no. 5, p. 43.Anonymous, 2010, China wants to hasten coalbed methane development: Oil & Gas Journal, v. 108.33, p. 84-87.Anonymous, 2010, KGS assessing carbon sequestration: American Oil & Gas Reporter, v. 53, no. 6, p. 154-155.Anonymous, 2010, Produced water seen as beneficial use: American Oil & Gas Reporter, v. 53, no. 12, p. 126-129.Antia, D.D.J., 1986, Kinetic method for modeling vitrinite reflectance: Geology, v. 14, p. 606-608.Apodaca, L.E., 2014, Peat: Earth, v. 59, no. 7/8, p. 109.Araujo, C.V., A.G. Borrego, B. Cardott, R.B.A. das Chagas, D. Flores, P. Gonçalves, P.C. Hackley, J.C. Hower, M.L. Kern, J. Kus, M. Mastalerz, J.G.M. Filho, J.de Olivera Mendonça, T.R. Menezes, J. Newman, I. Suarez-Ruiz, F.S. da Silva, and I.V. de Souza, 2014, Petrographic maturity parameters of a Devonian shale maturation series, Appalachian Basin, USA. ICCP Thermal Indices Working Group interlaboratory exercise: International Journal of Coal Geology, v. 130, p. 89-101.Arbuzov, S.I., A.V. Volostnov, A.M. Mezhibor, V.I., Rybalko, and S.S. Ilenok, 2014, Scandium (Sc) geochemistry in coals (Siberia, Russian far east, Mongolia, Kazakhstan, and Iran): International Journal of Coal Geology, v. 125, p. 22-35.Arbuzov, S.I., A.V. Volostnov, L.P. Rikhvanov, A.M. Mezhibor, and S.S. Ilenok, 2011, Geochemistry of radioactive elements (U, Th) in coal and peat of northern Asia (Siberia, Russian far east, Kazakhstan, and Mongolia): International Journal of Coal Geology, v. 86, p. 318-328.

Argall, G.O., Jr., ed., 1979, Coal exploration, v. 2: San Francisco, Miller Freeman Publications, Inc., 560 p.Armagnac, C., C.G.St.C. Kendall, C. Kuo, I. Lerche, and J. Pantano, 1988, Determination of paleoheat flux from vitrinite reflectance data, and from sterane and hopane isomer data: Journal of Geochemical Exploration, v. 30, p. 1-28.

Anand-Prakash, B.K. Misra, and B.D. Singh, 1996, Fluorescence microscopy in the evaluation of Indian Gondwana coals, in Gondwana nine (v. 2): Geological Survey of India, Ninth International Gondwana Symposium, p. 1265-1272.Anders, D., 1991, Geochemical exploration methods, in R.K. Merrill, ed., Source and migration processes and evaluation techniques: AAPG Treatise of Petroleum Geology, Handbook of Petroleum Geology, p. 89-95.

Anderson, L.L., 1988, Catalysis of coal liquefaction, in Y. Yurum, ed., New trends in coal science: Boston, Kluwer Academic Publishers, p. 361-381.Anderson, L.L., 1988, Coal liquefaction kinetics, in Y. Yurum, ed., New trends in coal science: Boston, Kluwer Academic Publishers, p. 339-359.

Andrews, W.M., J.C. Hower, J.C. Ferm, S.D. Evans, N.S. Sirek, M. Warrell, and C.F. Eble, 1996, A depositional model for the Taylor coal bed, Martin and Johnson counties, eastern Kentucky, in J.C. Hower and C.F. Eble, eds., Geology and petrology of Appalachian coals: International Journal of Coal Geology, v. 31, p. 151-167.

Anonymous, 2009, Geologic carbon sequestration opportunities in Pennsylvania: Pennsylvania Department of Conservation and Natural Resources, 150 p. http://www.dcnr.state.pa.us/info/carbon/mastercstareport2.pdf

Archer, P.L., and J. N. Kirr, 1984, Pennsylvanian geology, coal, and coalbed methane resources of the Illinois Basin—Illinois, Indiana, and Kentucky, in C.T. Rightmire, G.E. Eddy, and J.N. Kirr, eds., Coalbed methane resources of the United States: AAPG Studies in Geology 17, p. 105-134.

Arthur, D., B. Langhus, and V. Rawn-Schatzinger, 2003, Coalbed natural gas resources and produced water management: GasTIPS, v. 9, no. 3, p. 20-24.Arthur, D., B. Langhus, and V. Rawn-Schatzinger, 2003, Coalbed natural gas resources and produced water management: GasTIPS, v. 9, no. 3, p. 20-24. (part 1 of 3)Ashley, G.H., 1918, Cannel coal in the United States: U.S. Geological Survey Bulletin 659, 127 p.

ASTM, 1980, Standard method of test for oil from oil shale: Annual Book of American Society for Testing and Materials (ASTM) Standards, Part 25, D 3904-80, p. 513-515.ASTM, 1992, Manual on drilling, sampling, and analysis of coal: American Society for Testing and Material Manual 11, 72 p.ASTM, Annual book of ASTM standards: gaseous fuels; coal and coke: American Society for Testing and Materials, sec. 5, v. 5.05.Atlas, R., and J.H. Wendell, 2008, Low-power capacitive deionization method shows promise for treating coalbed methane produced water: World Oil, v. 229, no. 4, p. 231-234.Attanasi, E.D., 1998, Coal resources, new air quality standards, and sustainability: Nonrenewable Resources, v. 7, p. 271-279.

Averitt, P., 1975, Coal resources of the United States, January 1, 1974: U.S. Geological Survey Bulletin 1412, 131 p. (rank classification of coal by chemistry)Avila, C., T. Wu, and E. Lester, 2014, Petrographic characterization of coals as a tool to detect spontaneous combustion potential: Fuel, v. 125, p. 173-182.Avila, C., T. Wu, and E. Lester, 2014, Petrographic characterization of coals as a tool to detect spontaneous combustion potential: Fuel, v. 125, p. 173-182.

Ayers, W.B., Jr., 1991, Geologic evaluation of critical production parameters for coalbed methane resources: Quarterly Review of Methane from Coal Seams Technology, v. 8, no. 2, p. 27-33.

Ayers, W.B., Jr., 2002, Coalbed gas systems, resources, and production and a review of contrasting cases from the San Juan and Powder River Basins: AAPG Bulletin, v. 86, p. 1853-1890.

Ayers, W.B., Jr., and B.S. Kelso, 1989, Knowledge of methane potential for coalbed resources grows, but needs more study: Oil & Gas Journal, v. 87, no. 43, p. 64-67.Ayers, W.B., Jr., and S.D. Zellers, 1989, Geologic controls on occurrence and producibility of coalbed methane, Fruitland Formation, north-central San Juan basin, New Mexico: Proceedings of the 1989 Coalbed Methane Symposium, paper 8925, p. 75-86.Ayers, W.B., Jr., and W.R. Kaiser, eds., 1994, Coalbed methane in the Upper Cretaceous Fruitland Formation, San Juan basin, New Mexico and Colorado: New Mexico Bureau of Mines and Mineral Resources Bulletin 146, 216 p. (Colorado Geological Survey Resource Series 31)

Ayers, W.B., Jr., W.R. Kaiser, and J.R. Levine, 1993, Coal as source rock and gas reservoir: Birmingham, Alabama, 1993 Coalbed Methane Symposium, Short Course 1, 257 p.Ayoub, J., L. Colson, J. Hinkel, D. Johnston, and J. Levine, 1991, Learning to produce coalbed methane: Oilfield Review, v. 3, p. 27-40.

Bachu, S., 2002, Sequestration of CO2 in geological media in response to climate change: Road map for site selection using the transform of the geological space into CO2 space: Energy Conversion and Management, v. 43, p. 87-102.Bachu, S., 2008, CO2 storage in geological media: role, means, status and barriers to deployment: Progress in Energy and Combustion Science, v. 34, p. 254-273.Bachu, S., and K. Michael, 2003, Possible controls of hydrogeological and stress regimes on the producibility of coalbed methane in Upper Cretaceous—Tertiary strata of the Alberta basin, Canada: AAPG Bulletin, v. 87, p. 1729-1754.Bachu, S., and S. Stewart, 2002, Geological sequestration of anthropogenic carbon dioxide in the Western Canada sedimentary basin: suitability analysis: Journal Canadian Petroleum Technology, v. 41, no. 2, p. 32-40.Bachu, S., W.D. Gunter, and E.H. Perkins, 1994, Aquifer disposal of CO2: Hydrodynamic and mineral trapping: Energy Conversion and Management, v. 35, p. 269-279.Badin, E.J., 1984, Coal combustion chemistry-correlation aspects: Coal Science and Technology 6, Elsevier, New York, 259 p.

Bagherieh, A.H., J.C. Hower, A.R. Bagherieh, and E. Jorjani, 2008, Studies of the relationship between petrography and grindability for Kentucky coals using artificial neural network: International Journal of Coal Geology, v. 73, p. 130-138.Bailey, A., 1981, Chemical and mineralogical differences between Kittanning coal from marine-influenced vs. fluvial sequences: Journal of Sedimentary Petrology, v. 51, p. 383-395.

Bailey, J.G., A.G. Tate, C.F.K. Diessel, and T.F. Wall, 1990, A char morphology system with applications to coal combustion: Fuel, v. 69, p. 225-239.

Armagnac, C., J. Bucci, C.G.St.C. Kendall, and I. Lerche, 1989, Estimating the thickness of sediment removed at an unconformity using vitrinite reflectance data, in T.H. McCulloch and N. Naeser, eds., Thermal history of sedimentary basins: Springer-Verlag, p. 217-238.Arri, L.E., D. Yee, W.D. Morgan, and M.W. Jeansonne, 1992, Modeling coalbed methane production with binary gas sorption: Society of Petroleum Engineers, Rocky Mountain Regional Meeting, SPE Paper 24363, p. 459-472. (use of Nitrogen or CO 2 injection to desorb methane)

Ashley, M., 2005, Wyodak coal, Tongue River member of the Fort Union Formation, Powder River Basin, Wyoming: "no coal zones" and their effect on coalbed methane production, in P. Lufholm and D. Cox, eds., 2005 WTGS Fall Symposium: West Texas Geological Society, Publication No. 05-115, p. 67-82.

Attanasi, E.D., 1998, Relative importance of physical and economic factors in Appalachian coalbed gas assessment, in P.C. Lyons, ed., Special issue: Appalachian coalbed methane: International Journal of Coal Geology, v. 38, p. 47-59.

Axelson, D.E., R.J. Mikula, and V.A. Munoz, 1987, Characterization of coal oxidation in-situ and on a stockpile, in J.A. Moulijn, K.A. Nater, and H.A.G. Chermin, eds., International conference on coal science: Elsevier, p. 419-422.

Ayers, W.B., Jr., 1993, Geologic characterization of coalbed methane occurrence and producibility, in W.B. Ayers, Jr., W.R. Kaiser, and J.R. Levine, Coal as source rock and gas reservoir: Birmingham, Alabama, 1993 Coalbed Methane Symposium, Short Course 1, p. 121-187.

Ayers, W.B., Jr., 2003, Coalbed methane in the Fruitland Formation, San Juan Basin, western United States: a giant unconventional gas play, in M.T. Halbouty, ed., Giant oil and gas fields of the decade 1990-1999: AAPG Memoir 78, p. 159-188.

Ayers, W.B., Jr., S.K. Ruhl, M. Hoffman, J.A. Rushing, D.A. McVay, and R.I. Ramazanova, 2005, Low-rank coals of the Wilcox Group, east-central Texas: coalbed methane resources, potential for CO2 sequestration, and enhanced methane production, in P. Lufholm and D. Cox, eds., 2005 WTGS Fall Symposium: West Texas Geological Society, Publication No. 05-115, p. 43-65.Ayers, W.B., Jr., S.K. Ruhl, M. Hoffman, J.A. Rushing, D.A. McVay, and R.I. Ramazanova, 2005, Low-rank coals of the Wilcox Group, east-central Texas: coalbed methane resources, potential for CO2 sequestration, and enhanced methane production, in P. Lufholm and D. Cox, eds., 2005 WTGS Fall Symposium: West Texas Geological Society, Publication No. 05-115, p. 43-65.

Bachu, S., 2001, Geologic sequestration of anthropogenic carbon dioxide; applicability and current issues, in L.C. Gerhard, W.E. Harrison, and B.M. Hanson, eds., Geological perspectives of global climate change: AAPG Studies in Geology 47, p. 285-303.

Bagge, M.A., and M.L. Keeley, 1994, The oil potential of Mid-Jurassic coals in northern Egypt, in A.C. Scott and A.J. Fleet, eds., Coal and coal-bearing strata as oil-prone source rocks?: London, The Geological Society Special Publication 77, p. 183-200.

Bailey, H.E., B.W. Glover, S. Holloway, and S.R. Young, 1995, Controls of coalbed methane prospectivity in Great Britain, in M.K.G. Whateley and D.A. Spears, eds., European coal geology: London, Geological Society Special Publication 82, p. 251-265.Bailey, J.G., 1989, Sampling and testing of maceral concentrates for p.f. combustion, in C.G. Thomas and M.G. Strachan, eds., Proceedings of the Macerals ’89 symposium: North Ryde, NSW, CSIRO, p. 6-1 to 6-11. (pulverized fuel)

Bailey, N.J.L., 1981, Hydrocarbon potential of organic matter, in J. Brooks, ed., Organic maturation studies and fossil fuel exploration: San Francisco, Academic Press, p. 283-302.

Baines, S.J., and R.H. Worden, eds., 2004, Geological storage of carbon dioxide: London, Geological Society Special Publication 233, 255 p.Baird, R.A., and R.P. Philp, 1988, Hydrocarbon potential of the Upper Jurassic/Lower Cretaceous of the Australian NW shelf: Journal of Petroleum Geology, v. 11, p. 125-139.Bakel, A.J., 1987, Sulfur and nitrogen compounds in oils, asphaltenes, kerogens, and coals: Norman, University of Oklahoma unpublished M.S. thesis, 93 p.Baker, D.J., 1998, Light years ahead: University of Kentucky, Center for Applied Energy Research, Energeia, v. 9, no. 5, p. 1-3. (types of combustion)Baker, E.C., D.C. Oyler, J.H. Perry, and G.L. Finfinger, 1984, Economic evaluation of directional drilling for methane drainage from coalbeds: U.S. Bureau of Mines Report of Investigations 8842, 11 p.Balan, H.O., and F. Gumrah, 2009, Assessment of shrinkage-swelling influences in coal seams using rank-dependent physical coal properties: International Journal of Coal Geology, v. 77, p. 203-213.Balashov, V.N., G.D. Guthrie, J.A. Hakala, C.L. Lopano, J.D. Rimstidt, and S.L. Brantley, 2013, Predictive modeling of CO2 sequestration in deep saline sandstone reservoirs: Impacts of geochemical kinetics: Applied Geochemistry, v. 30, p. 41-56.

Ball, D., N. Gupta, and B. Metzger, 2007, Energy industry examining CO2 sequestration options: Oil & Gas Journal, v. 105.18, p. 20-27.Ban, H., J.L. Schaefer, and J.M. Stencel, 1995, Electrostatic separation of powdered materials: beneficiation of coal and fly ash: Energeia, v. 6, no. 4, p. 1-3.Ban, H., T.X. Li, J.C. Hower, J.L. Schaefer, and J.M. Stencel, 1997, Dry triboelectrostatic beneficiation of fly ash: Fuel, v. 76, p. 801-805.Bandopadhyay, A.K., 2010, A study on the abundance of quartz in thermal coals of India and its relation to abrasion index: Development of predictive model for abrasion: International Journal of Coal Geology, v. 84, p. 63-69.Bandopadhyay, A.K., 2010, Determination of quartz content for Indian coals using an FTIR technique: International Journal of Coal Geology, v. 81, p. 73-78.Banerjee, A., A.K. Sinha, A.K. Jain, N.J. Thomas, K.N. Misra, and K. Chandra, 1998, A mathematical representation of Rock-Eval hydrogen index vs Tmax profiles: Organic Geochemistry, v. 28, p. 43-55.Banerjee, B.D., 1987, A new approach to the determination of methane content in coal seams: International Journal of Mining and Geological Engineering, v. 5, p. 369-376.Banerjee, B.D., 1988, Spacing of fissuring network and rate of desorption of methane from coals: Fuel, v. 67, p. 1584-1586. (cleat)Banerjee, I., W. Kalkreuth, and E.H. Davies, 1996, Coal seam splits and transgressive-regressive coal couplets: a key to stratigraphy of high-freqency sequences: Geology, v. 24, p. 1001-1004.Baolin, T., W. Shijun, G. Yingting, L. Hongqi, C. Guiren, and Z. Hong, 1996, Flora of Palaeozoic coal balls of China: The Palaeobotanist, v. 45, p. 247-254.Baranger, R., L. Martinez, J.-L. Pittion, and J. Pouleau, 1991, A new calibration procedure for fluorescence measurements of sedimentary organic matter: Organic Geochemistry, v. 17, p. 467-475.

Barghoorn, E.S., 1952, Degradation of plant tissues in organic sediments: Journal of Sedimentary Petrology, v. 22, p. 34-41.Barker, C.E., 1982, A rapid method for concentrating sedimentary organic matter for vitrinite reflectance analysis: Journal of Sedimentary Petrology, v. 52, p. 663-664.

Barker, C.E., 1991, An update on the suppression of vitrinite reflectance: TSOP Newsletter, v. 8, no. 4, p. 8-11.Barker, C.E., 1991, An update on the suppression of vitrinite reflectance: TSOP Newsletter, v. 8, no. 4, p. 8-11.Barker, C.E., 1991, Implications for organic maturation studies of evidence for a geologically rapid increase and stabilization of vitrinite reflectance at peak temperature: Cerro Prieto geothermal system, Mexico: AAPG Bulletin, v. 75, p. 1852-1863.Barker, C.E., 1994, Physical and geochemical conditions of organic metamorphism next to selected dikes, Victoria, Australia: The University of Adelaide, unpublished PhD dissertation, 293 p.Barker, C.E., 1995, Physical and geochemical conditions of organic metamorphism next to selected dikes, Victoria, Australia: Unpublished PhD dissertation, Department of Geology and Geophysics, University of Adelaide, 430 p.Barker, C.E., 1996, A comparison of vitrinite reflectance measurements made in whole-rock and dispersed organic matter concentrate mounts: Organic Geochemistry, v. 24, p. 251-256.Barker, C.E., 1996, A comparison of vitrinite reflectance measurements made on whole-rock and dispersed organic matter concentrate mounts: Organic Geochemistry, v. 24, p. 251-256.Barker, C.E., 1996, A field and laboratory procedure to desorb coal bed gases from drill core and cuttings: U.S. Geological Survey, Open-File Report 96-658.

Barker, C.E., 2006, Visual detection of gas shows from coal core and cuttings using liquid leak detector: Bulletin of Canadian Petroleum Geology, v. 54, p. 292-297.

Barker, C.E., and M.J. Pawlewicz, 1993, An empirical determination of the minimum number of measurements needed to estimate the mean random vitrinite reflectance of disseminated organic matter: Organic Geochemistry, v. 20, no. 6, p. 643-651.Barker, C.E., and M.J. Pawlewicz, 1993, An empirical determination of the minimum number of measurements needed to estimate the mean random vitrinite reflectance of disseminated organic matter: Organic Geochemistry, v. 20, p. 643-651.

Barker, C.E., and R.H. Goldstein, 1990, Fluid-inclusion technique for determining maximum temperature in calcite and its comparison to the vitrinite reflectance geothermometer: Geology, v. 18, p. 1003-1006.

Baldwin, R.M., 1991, Correlation of coal properties with hydroliquefaction reactivity, a brief review, in H.H. Schobert, K.D. Bartle, and L.J. Lynch, eds., Coal science II: Washington, D.C., American Chemical Society, Symposium Series 461, p. 171-181.

Barghoorn, E.S., 1952, Degradation of plant materials and its relation to the origin of coal, in Second conference on the origin and constitution of coal: Nova Scotia Department of Mines, p. 181-207.

Barker, C.E., 1989, Temperature and time in the thermal maturation of sedimentary organic matter, in N.D. Naeser and T.H. McCulloh, eds., Thermal history of sedimentary basins: New York, Springer-Verlag, p. 73-98.

Barker, C.E., 2003, A first report of significant coalbed methane production from a Paleozoic coal, Kerr Basin, west-central Texas, in M.R. Silverman, ed., Emerging coalbed methane plays of North America (part 3): Petroleum Frontiers, v. 19, no. 2, p. 31-36.Barker, C.E., 2003, Coalbed methane prospects of the Tyonek Formation, onshore northern Cook Inlet Basin, south-central Alaska, in M.R. Silverman, ed., Emerging coalbed methane plays of North America (part 3): Petroleum Frontiers, v. 19, no. 2, p. 9-19.

Barker, C.E., and M.J. Pawlewicz, 1986, A surface vitrinite reflectance anomaly related to the Bell Creek oil field, Montana, in M.J. Davidson, ed., Unconventional methods for exploration: Dallas, Southern Methodist Press, p. 125-146.Barker, C.E., and M.J. Pawlewicz, 1986, The correlation of vitrinite reflectance with maximum temperature in humic organic matter, in G. Buntebarth and L. Stegena, eds., Paleogeothermics: Springer-Verlag, Lecture Notes in Earth Sciences 5, p. 79-93.

Barker, C.E., and M.J. Pawlewicz, 1994, Calculation of vitrinite reflectance from thermal histories and peak temperatures, a comparison of methods, in P.K. Mukhopadhyay and W.G. Dow, eds., Vitrinite reflectance as a maturity parameter, applications and limitations: Washington, D.C., American Chemical Society, ACS. Symposium Series 570, p. 216-229.Barker, C.E., and R.H. Goldstein, 1990, A fluid-inclusion technique for determining peak temperature and its application to establish a refined calibration for the vitrinite reflectance geothermometer (abstract), in L.M.H. Carter, ed., USGS research on energy resources—1990 program and abstracts: U.S. Geological Survey Circular 1060, p. 6-8.

Barker, C.E., and T. Dallegge, 2006, Secondary gas emissions during coal desorption, Marathon Grassim Oskolkoff-1 well, Cook Inlet Basin, Alaska: implications for resource assessment: Bulletin of Canadian Petroleum Geology, v. 54, p. 273-291.Barker, C.E., and Y. Bone, 1994, The minimal response to contact metamorphism by the Devonian Buchan Caves Limestone, Buchan Rift, Victoria, Australia: Organic Geochemistry, v. 22, p. 151-164.Barker, C.E., and Y. Bone, 1994, The minimal response to contact metamorphism by the Devonian Buchan Caves Limestone, Buchan Rift, Victoria, Australia: Organic Geochemistry, v. 22, p. 151-164.Barker, C.E., J.G. Clough, S.B. Roberts, and B. Fisk, 2002, Coalbed methane in northern Alaska: potential resources for rural use and added supply for the proposed trans-Alaska gas pipeline (abstract): AAPG Annual Convention Official Program, v. 11, p. A13.Barker, C.E., J.G. Clough, S.B. Roberts, and R. Fisk, 2002, Coalbed methane in northern Alaska: potential resources for rural use and added supply for the proposed Trans-Alaska gas pipeline (abstract): AAPG Bulletin, v. 86, p. 1135.

Barker, C.E., M. Gose, R.J. Scott, P.D. Warwick, J.R. SanFilipo, J.M. Klein, and R.W. Hook, 2002, The Sacatosa coalbed methane field: a first for Texas (abstract): AAPG Annual Convention Official Program, v. 11, p. A13.Barker, C.E., M.D. Lewan, and M.J. Pawlewicz, 2007, The influence of extractable organic matter on vitrinite reflectance suppression: A survey of kerogen and coal types: International Journal of Coal Geology, v. 70, p. 67-78.

Barker, C.E., R.C. Johnson, B.L. Crysdale, and A.C. Clark, 1991, A field and laboratory procedure for desorbing coal gases: USGS Open-File Report OF 91-0563, 16 p.Barker, C.E., T.A. Dallegge, and A.C. Clark, 2002, USGS coal desorption equipment and a spreadsheet for analysis of lost and total gas from canister desorption measurements: U.S. Geological Survey Open File Report 02-496, 13 p.

Barker, C.E., W. Heck, and C. Eble, 2003, Coalbed methane in Late Pennsylvanian to Early Permian coal, Kerr Basin, Edwards County, Texas: Gulf Coast Association of Geological Societies Transactions, v. 53, p. 38-50.

Barnard, P.C., B.S. Cooper, and M.J. Fisher, 1980, Organic maturation and hydrocarbon generation in the Mesozoic sediments of the Sverdrup basin, Arctic Canada: Proceedings of the IV International Palynological Conference, Lucknow (1976-1977), v. 2, p. 581-588.Barnes, D.A., D.H. Bacon, and S.R. Kelley, 2009, Geological sequestration of carbon dioxide in the Cambrian Mount Simon Sandstone: Regional storage capacity, site characterization, and large-scale injection feasibility, Michigan Basin: Environmental Geosciences, v. 16, no. 3, p. 163-183.Barnes, M.A., W.C. Barnes, and R.M. Bustin, 1984, Diagenesis 8. Chemistry and evolution of organic matter: Geoscience Canada, v. 11, p. 103-114.Barnhart, E.P., K.B. De León, B.D. Ramsay, A.B. Cunningham, and M.W> Fields, 2013, Investigation of coal-associated bacterial and archaeal populations from a diffusive microbial sampler (DMS): International Journal of Coal Geology, v. 115, p. 64-70.

Barrick, J.E., D.J. Over, C.R. Landis, and W.L. Borst, 1990, Conodont fluorescence emission spectra: potential for high resolution evaluation of organic maturation in hydrocarbon-bearing basins (abstract): Geological Society of America South Central Section, Abstracts with Programs, v. 22, no. 1, p. 1-2.

Barss, M.S., and G.L. Williams, 1973, Palynology and nannofossil processing techniques: Geological Survey of Canada, Paper 73-26, 25 p.

Baruah, B.P., and P. Khare, 2010, Mobility of trace and potentially harmful elements in the environment from high sulfur Indian coal mines: Applied Geochemistry, v. 25, p. 1621-1631.Baruah, M.K., and M.C. Upreti, 1994, Incorporation of sulfur in coal precursors: Fuel, v. 73, p. 71.Baskin, D.K., 1979, A method of preparing phytoclasts for vitrinite reflectance analysis: Journal of Sedimentary Petrology, v. 49, p. 633-635.Baskin, D.K., 1997, Atomic H/C ratio of kerogen as an estimate of thermal maturity and organic matter conversion: AAPG Bulletin, v. 81, p. 1437-1450.

Bastian, P.A., O.F.R. Wirth, L. Wang, and G.W. Voneiff, 2005, New techniques key in ‘dry’ CBM play: American Oil & Gas Reporter, v. 48, no. 12, p. 65-75.Batten, D.J., 1980, Use of transmitted light microscopy of sedimentary organic matter for evaluation of hydrocarbon source potential: Proceedings of the IV International Palynological Conference, Lucknow (1976-1977), v. 2, p. 589-594.

Batten, D.J., 1982, Palynofacies, palaeoenvironment and petroleum: Journal of Micropaleontology, v. 1, p. 107-114.

Batten, D.J., and M.C. Keen, eds., 1989, Northwest European micropalaeontology and palynology: New York, John Wiley and Sons, Inc., 298 p.

Battistutta, E., M. Lutynski, H. Bruining, K.-H. Wolf, and S. Rudolph, 2012, Adequacy of equation of state models for determination of adsorption of gas mixtures in a namometric set up: International Journal of Coal Geology, v. 89, p. 114-122.Battistutta, E., P. van Hemert, M. Lutynski, H. Bruining, and K.-H. Wolf, 2010, Swelling and sorption experiments on methane, nitrogen and carbon dioxide on dry Selar Cornish coal: International Journal of Coal Geology, v. 84, p. 39-48.

Barker, C.E., L.R. Biewick, P.D. Warwick, and J.R. SanFilipo, 2000, Preliminary Gulf Coast coalbed methane exploration maps; depth to Wilcox, apparent Wilcox thickness, and vitrinite reflectance: U.S. Geological Survey, Open-File Report 00-0113. (see http://greenwood.cr.usgs.gov/pub/open-file-reports/ofr-00-0113/wlcxmaps.htm)

Barker, C.E., P.D. Warwick, M. Gose, and R.J. Scott, 2003, Olmos coal, Maverick Basin, south Texas: from prospect to production, in M.R. Silverman, ed., Emerging coalbed methane plays of North America (part 2): Denver, CO, Petroleum Frontiers, v. 18, no. 4, p.1-10.

Barker, C.E., T.C. Bartke, P.G. Hatcher, and T.A. Daws, 1993, An empirical correlation between coal bed gas with Rock-Eval pyrolysis and 13C NMR results, Cretaceous Mesaverde and Meeteetse formations, Wind River basin, Wyoming, in W.R. Keefer and others, eds., Wyoming Geological Association special symposium on oil and gas and other resources of the Wind River basin, Wyoming: Casper, Wyoming Geological Association, p. 243-256.

Barnard, P.C., A.G. Collins, and B.S. Cooper, 1981, Identification and distribution of kerogen facies in a source rock horizon - examples from the North Sea basin, in J. Brooks, ed., Organic maturation studies and fossil fuel exploration: New York, Academic Press, p. 271-281.Barnard, P.C., A.G. Collins, and B.S. Cooper, 1981, Identification and distribution of kerogen facies in a source rock horizon - examples from the North Sea basin, in J. Brooks, ed., Organic maturation studies and fossil fuel exploration: San Francisco, Academic Press, p. 271-282.

Barraza, J., M. Cloke, and A. Belghazi, 1997, Improvements in direct coal liquefaction using beneficial coal fractions, in R. Gayer and J. Pesek, eds., European coal geology and technology: London, Geological Society Special Publication 125, p. 349-356.

Barriocanal, C., J.W. Patrick, A. Walker, and A.R. Walker, 1995, The identification of dangerously coking coals, in J.A. Pajares and J.M.D. Tascon, eds., Coal science: New York, Elsevier, Coal Science and Technology 24, v. 1, p. 989-992.Barriocanal, C., S. Hanson, J.W. Patrick, and A. Walker, 1995, Quality of interfaces between textural components in metallurgical cokes, in J.A. Pajares and J.M.D. Tascon, eds., Coal science: New York, Elsevier, Coal Science and Technology 24, v. 1, p. 1061-164.

Bartholomew, C.H., S.J. Butala, J.C. Medina, M.L. Lee, T.Q. Taylor, and D.B. Andrus, 1999, Mineral-catalyzed formation of natural gas during coal maturation, in M. Mastalerz, M. Glikson, and S.D. Golding, eds., Coalbed methane: scientific, environmental and economic evaluation: Boston, Kluwer Academic Publishers, p. 279-296.

Baskin, D.K., 2001, Comparison between atomic H/C and Rock-Eval Hydrogen Index as an indicator of organic matter quality, in C.M. Isaacs and J. Rullkötter, eds., The Monterey Formation from rocks to molecules: New York, Columbia University Press, p. 230-240.

Batten, D.J., 1981, Palynofacies, organic maturation and source potential for petroleum, in J. Brooks, ed., Organic maturation studies and fossil fuel exploration: San Francisco, Academic Press, p. 201-223.

Batten, D.J., 1983, Identification of amorphous sedimentary organic matter by transmitted light microscopy, in J. Brooks, ed., Petroleum geochemistry and exploration of Europe: Boston, Blackwell Scientific Publications, The Geological Society Special Publication 12, p. 275-287.Batten, D.J., 1996, Palynofacies and palaeoenvironmental interpretation, in J. Jansonius and D.C. McGregor, eds., Palynology: principles and applications: American Association of Stratigraphic Palynologists, v. 3, p. 1011-1064.Batten, D.J., 1996, Palynofacies and petroleum potential, in J. Jansonius and D.C. McGregor, eds., Palynology: principles and applications: American Association of Stratigraphic Palynologists, v. 3, p. 1065-1084.

Batten, D.K., and H.R. Grenfell, 1996, Botryococcus, in J. Jansonius and D.C. McGregor, eds., Palynology: principles and applications: American Association of Stratigraphic Palynologists, v. 1, p. 205-214.

Baumann, D.R., 1982, The occurrence and distribution of mineral matter in coal lithotypes in the Herrin (No. 6) coal seam under marine and non-marine influences: Carbondale, Southern Illinois University, unpublished M.S. thesis, 151 p.Baumann, D.R., 1982, The occurrence and distribution of mineral matter in coal lithotypes in the Herrin (No. 6) coal seam under marine and non-marine influences: Carbondale, Southern Illinois University, unpublished M.S. thesis, 151 p.

Baxby, M., R.L. Patience, and L.D. Bartle, 1994, The origin and diagenesis of sedimentary organic nitrogen: Journal of Petroleum Geology, v. 17, p. 211-229.Baxter, R.W., and A.L. Hornbaker, 1965, Pennsylvanian fossil plants from Kansas coal balls: Kansas Geological Survey, a field conference guidebook for the annual meeting of the Geological Society of America and associated societies, 34 p.Bayan, M.R., and J.C. Hower, 2012, Illite crystallinity and coal metamorphism for selected central Appalachian coals and shales: International Journal of Coal Geology, v. 94, p. 167-172.Bayer, J.L., and G.H. Denton, 1966, Applications of coke microscopy to plant problems: Blast Furnace and Steel Plant for December, p. 1133-1142.

BCRA Quarterly, 1986, Coal characteristics important for uses other than cokemaking. Part 1: combustion, gasification, liquefaction: BCRA Quarterly, v. 11, p. 44-62.Beach, J.O., 1945, Oklahoma asphaltite deposits: Oklahoma Geological Survey, The Hopper, v. 5, p. 51-60.Beafore, F.J., K.E. Cawiezel, and C.T. Montgomery, 1984, "Oxidized coal": what it is and how it affects your preparation plant performance: Journal of Coal Quality, v. 3, p. 17-23.Beamish, B.B., 1994, Proximate analysis of New Zealand and Australian coals by thermogravimetry: New Zealand Journal of Geology and Geophysics, v. 37, p. 387-392.

Beamish, B.B., and A. Arisoy, 2007, Effect of mineral matter on coal self-heating rate: Fuel, v. 87, p. 125-130.

Beamish, B.B., and P.J. Crosdale, 1998, Instantaneous outbursts in underground coal mines: an overview and association with coal type: International Journal of Coal Geology, v. 35, p. 27-55.Beamish, B.B., and P.J. Crosdale, 1998, Instantaneous outbursts in underground coal mines: an overview and association with coal type: International Journal of Coal Geology, v. 35, p. 27-55.Beamish, B.B., M.A. Barakat, and J.D. St. George, 2001, Spontaneous-combustion propensity of New Zealand coals under adiabatic conditions: International Journal of Coal Geology, v. 45, p. 217-224.Bearce, D. N., J. C. Pashin, and W. E. Osborne, eds., 1997, Geology of the Coosa coalfield: Alabama Geological Society 34th Annual Field Trip Guidebook, 79 p.Beaton, A., D. Chen, C. Pana, and R.J.H. Richardson, 2002, Coal and coalbed methane potential of Upper Cretaceous-Tertiary strata in the plains region, Alberta, Canada (abstract): AAPG Annual Convention Official Program, v. 11, p. A15.Beaton, A., W. Langenberg, and C. Pană, 2006, Coalbed methane resources and reservoir characteristics from the Alberta Plains, Canada: International Journal of Coal Geology, v. 65, p. 93-113.Beaumont, E.A., 1979, Depositional environments of Fort Union sediments (Tertiary, northwest Colorado) and their relation to coal: AAPG Bulletin, v. 63, p. 194-217.

Bechtel, A., J. Jia, S.A.I. Strobl, R.F. Sachsenhofer, Z. Liu, R. Gratzer, and W. Püttmann, 2012, Palaeoenvironmental conditions during deposition of the Upper Cretaceous oil shale sequences in the Songliao Basin (NE China): Implications from geochemical analysis: Organic Geochemistry, v. 46, p. 76-95.Bechtel, A., M. Hámor-Vidó, R.F. Sachsenhofer, D. Reischenbacher, R. Gratzer, and W. Püttmann, 2007, The middle Eocene Márkushegy subbituminous coal (Hungary): Paleoenvironmental implications from petrographical and geochemical studies: International Journal of Coal Geology, v. 72, p. 33-52.Bechtel, A., M. Markic, R.F. Sachsenhofer, B. Jelen, R. Gratzer, A. Lücke, and W. Püttmann, 2004, Paleoenvironment of the upper Oligocene Trbovlje coal seam (Slovenia): International Journal of Coal Geology, v. 57, p. 23-48.Bechtel, A., R. Gratzer, and R.F. sachsenhofer, 2001, Chemical characteristics of Upper Cretaceous (Turonian) jet of the Gosau Group of Gams/Hieflau (Styria, Austria): International Journal of Coal Geology, v. 46, p. 27-49. (bituminous driftwood is collotelinite)Bechtel, A., R.F. Sachsenhofer, A. Zdravkov, I. Kostova, and R. Gratzer, 2005, Influence of floral assemblage, facies and diagenesis on petrography and organic geochemistry of the Eocene Bourgas coal and the Miocene Maritza-East lignite (Bulgaria): Organic Geochemistry, v. 36, p. 1498-1522. (uses groundwater index)Bechtel, A., R.F. Sachsenhofer, I. Kolcon, R. Gratzer, A. Otto, and W. Püttmann, 2002, Organic geochemistry of the Lower Miocene Oberdorf lignite (Styrian basin, Austria): its relation to petrography, palynology and the palaeoenvironment: International Journal of Coal Geology, v. 51, p. 31-57.

Beecy, D.J., and V.A. Kuuskraa, 2001, Status of U.S. geologic carbon sequestration research and technology: Environmental Geosciences, v. 8, p. 152-159.

Beeston, J.W., 1987, Aspects of inertinite formation and deposition in the Denison Trough, Queensland: Australian Coal Geology, v. 7, p. 33-45.Beeston, J.W., 1992, Resino-inertinites of Indian Permian coals—their origin, genesis and classification: comment: International Journal of Coal Geology, v. 21, p. 283-285.

Beeston, J.W., and G.R. Wood, 1986, Quantitative autofluorescence variation in a low rank Permian palynomorph assemblage: Geological Survey of Queensland, Publication 387, p. 29-40.

Bauert, H., 1994, The Baltic oil shale basin: an overview, in Proceedings 1993 Eastern Oil Shale Symposium: Lexington, University of Kentucky Institute for Mining and Minerals Research, p. 411-421.

Baumgardner, R.W., Jr., 1991, Lineament analysis of northern San Juan Basin, New Mexico and Colorado—Applications to coalbed methane exploration, in S.D. Schwochow, D.K. Murray, and M.F. Fahy, eds., Coalbed methane of western North America: Denver, CO, Rocky Mountain Association of Geologists Guidebook, p. 21-34.

Bayliss, G.S., and L.B. Magoon, 1988, Organic facies and thermal maturity of sedimentary rocks in the National Petroleum Reserve in Alaska, in G. Cryc, ed., Geology and exploration of the National Petroleum Reserve of Alaska, 1974-1982: USGS Professional Paper 1399, p. 489-518.

Beamish, B.B., 2005, Comparison of the R70 self-heating rate of New Zealand and Australian coals to Suggate rank parameter, in J.C. Hower and S.F. Greb, eds., Geologic hazards in coal mining: International Journal of Coal Geology, v. 64, p. 139-144.

Beamish, B.B., and D.G. Blazak, 2005, Relationship between ash content and R70 self-heating rate of Callide coal, in J.C. Hower and S.F. Greb, eds., Geologic hazards in coal mining: International Journal of Coal Geology, v. 64, p. 126-132.Beamish, B.B., and G.R. Hamilton, 2005, Effect of moisture content on the R70 self-heating rate of Callide coal, in J.C. Hower and S.F. Greb, eds., Geologic hazards in coal mining: International Journal of Coal Geology, v. 64, p. 133-138.

Beaver, F.W., D.J. Daly, G.H. Groenewold, C.R. Schmit, J.E. Boysen, J.M. Evans, J.R. Covell, and R.A. Kuhnel, 1991, The status and future of underground coal gasification, in R.B. Finkelman and D.C. Peters, eds., Practical applications of coal geology: Journal of Coal Quality, v. 10, no. 3, p. 116-126.Beaver, F.W., G.H. Groenewold, C.R. Schmit, D.J. daly, and R.L. Oliver, 1991, The role of hydrogeology in underground coal gasification with an example from the Rocky mountain 1 (RM1) test, Carbon County, Wyoming, in D.C. Peters, ed., Geology in coal resource utilization: Fairfax, VA, Techbooks, p. 169-186.

Beck, C.B., K. Coy, and R. Schmid, 1982, Observations on the fine structure of Callixylon wood: American Journal of Botany, v. 69, p. 54076. (origin of fusain, p. 68-70)

Beeley, T.J., J.C. Crelling, J.R. Gibbins, A.C. Scott, and J. Williamson, 1995, Observations of maceral and mineral heterogeneity in pulverised coals, in J.A. Pajares and J.M.D. Tascon, eds., Coal science: New York, Elsevier Coal Science and Technology 24, v. 1, p. 203-206.Beeley, T.J., J.C. Crelling, J.R. Gibbons, R. Hurt, C.K. Man, and J. Williamson, 1995, Coal char reactivity characterisation for burn-out prediction in utility boilers, in J.A. Pajares and J.M.D. Tascon, eds., Coal science: New York, Elsevier, Coal Science and Technology 24, v. 1, p. 615-618.

Beeston, J.W., 1995, Coal rank and vitrinite reflectivity, in C.R. Ward and others, eds., Geology of Australian coal basins: Geological Society of Australia Coal Geology Group, Special Publication 1, p. 83-92.Beeston, J.W., 1995, Coal rank and vitrinite reflectivity, in C.R. Ward, and others, eds., Geology of Australian coal basins: Geological Society of Australia Coal Geology Group, Special Publication 1, p. 83-92. (origin of desmocollinite and telocollinite)

Begossi, R., and J.C.D. Fávera, 2002, Catastrophic floods as a possible cause of organic matter accumulation giving rise to coal, Paraná Basin, Brazil: International Journal of Coal Geology, v. 52, p. 83-89.Behar, F., V. Beaumont, B. De, and H.L. Penteado, 2001, Rock-Eval 6 technology: performances and developments: Oil & Gas Science and Technology – Revue du l’Institute Français du Petrole, v. 56, p. 111-134.Beinlich, A., H. Austrheim, J. Glodny, M. Erambert, and T.B. Andersen, 2010, CO2 sequestration and extreme Mg depletion in serpentinized peridotite clasts from the Devonian Solund Basin, SW-Norway: Geochimica et Cosmochimica Acta, v. 74, p. 6935-6964.Belaid, A., B.M. Krooss, and R. Littke, 2010, Thermal history and source rock characterization of a Paleozoic section in the Awbari Trough, Murzuq Basin, SW Libya: Marine and Petroleum Geology, v. 27, p. 612-632.Belcher, C.M., M.E. Collinson, A.R. Sweet, A.R. Hildebrand, and A.C. Scott, 2003, Fireball passes and nothing burns—The role of thermal radiation in the Cretaceous-Tertiary event: Evidence from the charcoal record of North America: Geology, v. 31, p. 1061-1064.

Belkin, H.E., S.J. Tewalt, J.C. Hower, J.D. Stucker, and J.M.K. O’Keefe, 2009, Geochemistry and petrology of selected coal samples from Sumatra, Kalimantan, Sulawesi, and Papua, Indonesia: International Journal of Coal Geology, v. 77, p. 260-268.Belkin, H.E., S.J. Tewalt, J.C. Hower, J.D. Stucker, J.M.K. O’Keefe, C.A. Tatu, and G. Buia, 2010, Petrography and geochemistry of Oligocene bituminous coal from the Jiu Valley, Petroşani Basin (southern Carpathian Mountains), Romania: International Journal of Coal Geology, v. 82, p. 68-80.Bell, J.S., 2006, In-situ stress and coal bed methane potential in western Canada: Bulletin of Canadian Petroleum Geology, v. 54, p. 197-220.

Bell, K.G., 1960, Uranium and other trace elements in petroleums and rock asphalts: U.S.G.S. Professional Paper 356-B, p. 45-65.

Bend, S.L., 1992, The origin, formation and petrographic composition of coal: Fuel, v. 71, p. 851-870.Bend, S.L., 1992, The origin, formation and petrographic composition of coal: Fuel, v. 71, p. 851-870.Bend, S.L., and D.M. Kosloski, 1993, A petrographic examination of coal oxidation: International Journal of Coal Geology, v. 24, p. 233-243.

Bend, S.L., I.A.S. Edwards, and H. Marsh, 1991, Coal provincialism, coal characterization and char formation: Fuel, v. 70, p. 1147-1150.

Bend, S.L., I.A.S. Edwards, and H. Marsh, 1992, The influence of rank upon char morphology and combustion: Fuel, v. 71, p. 493-501.Benedict, L.G., and R.R. Thompson, 1976, Selection of coals and coal mixes to avoid excessive coking pressure: Ironmaking Proceedings, AIME, v. 35, p. 276-288.Benedict, L.G., and R.R. Thompson, 1980, Coke/carbon reactions in the study of factors affecting coke quality: International Journal of Coal Geology, v. 1, p. 19-34.Benedict, L.G., and W.F. Berry, 1964, Recognition and measurement of coal oxidation: Monroeville, PA, Coal Research, 41 p.

Benedict, L.G., R.R. Thompson, and R.O. Wenger, 1968, Relationship between coal petrographic composition and coke stability: Blast Furnace and Coke Plant, v. 56, no. 3, p. 217-224.Benedict, L.G., R.R. Thompson, J. Shigo, and R. Aikman, 1968, Pseudovitrinite in Appalachian coking coals: Fuel, v. 47, p. 125-143.Benedict, L.G., R.R. Thompson, J.J. Shigo, and R.P. Aikman, 1968, Pseudovitrinite in Appalachian coking coals: Fuel, v. 47, p. 125-143.Benedict, L.G., R.R. Thompson, J.J. Shigo, III, and R.P. Aikman, 1968, Pseudovitrinite in Appalachian coking coals: Fuel, v. 47, p. 125-143.Bengtsson, M., 1987, Combustion behavior for a coal containing a high proportion of pseudovitrinite: Fuel Processing Technology, v. 15, p. 201-212.Bengtsson, M., 1987, Combustion behavior for a range of coals of various origins and petrographic compositions: 1987 International Conference on Coal Science, Elsevier, p. 893-896.Benito, A.M., M.T. Martinez, V. Cebolla, I. Fernandez, and J.L. Miranda, 1993, Hydrotreating of distillates from Spanish coal liquefaction: Erdöl und Kohle-Erdgas-Petrochemie, v. 46, no. 2, p. 78-80.

Bensley, D.F., and A. Davis, 1988, The use of light-emitting diodes as fluorescence standards and the fluorescence intensity of macerals: Organic Geochemistry, v. 12, p. 345-349.Bensley, D.F., and J.C. Crelling, 1992, Low intensity spectral analysis (LISA) of coal macerals and the assessment of DGC fractions: Organic Geochemistry, v. 18, p. 365-372.Bensley, D.F., and J.C. Crelling, 1993, The use of rotational polarization reflectance in the characterization of fine particulate macerals: Proceedings of the IEA International Conference on Coal Science, v. 1, p. 578-581.

Bensley, D.F., and J.C. Crelling, 1994, The inherent heterogeneity within the vitrinite maceral group: Fuel, v. 73, p. 1306-1316.Bensley, D.F., and J.C. Crelling, 1994, The inherent heterogeneity within the vitrinite maceral group: Fuel, v. 73, p. 1306-1316.Benson, S.M., and D.R. Cole, 2008, CO2 sequestration in deep sedimentary formations: Elements, v. 4, p. 325-331.Berbesi, L.A., G. Márquez, M. Martínez, and A. Requena, 2009, Evaluating the gas content of coals and isolated maceral concentrates from the Paleocene Guasare coalfield, Venezuela: Applied Geochemistry, v. 24, p. 1817-1824.

Belkin, H.E., B. Zheng, D. Zhou, and R.B. Finkelman, 2008, Chronic arsenic poisoning from domestic combustion of coal in rural China: A case study of the relationship between Earth materials and human health, in B. De Vivo, H.E. Belkin, and A. Lima, eds., Environmental geochemistry: Elsevier, p. 401-420.

Bell, J.S., and S. Bachu, 2003, In situ stress magnitude and orientation estimates for Cretaceous coal-bearing strata beneath the plains area of central and southern Alberta: Bulletin of Canadian Petroleum Geology, v. 51, p. 1-28.

Bell, K.G., and J.M. Hunt, 1963, Native bitumens associated with oil shales, in I.A. Breger, ed., Organic geochemistry: The Macmillan Company, A Pergamon Press Book, Earth Science Series, Monograph 16, p. 333-366.

Bend, S.L., and D.M. Kosloski, 1995, Advances in the fluorescence microscopy of low rank coals, in J.A. Pajares and J.M.D. Tascon, eds., Coal science, v. 1: New York, Elsevier, Coal Science and Technology 24, p. 251-254.Bend, S.L., and D.M. Kosloski, 1995, Advances in the fluorescence microscopy of low rank coals, in J.A. Pajares and J.M.D. Tascon, eds., Coal science: New York, Elsevier, Coal Science and Technology 24, v. 1, p. 251-254.

Bend, S.L., I.A.S. Edwards, and H. Marsh, 1991, Effects of oxidation and weathering on char formation and coal combustion, in H.H. Schobert, K.D. Bartle, and L.J. Lynch, eds., Coal science II: American Chemical Society Symposium Series 461, p. 284-298.Bend, S.L., I.A.S. Edwards, and H. Marsh, 1991, Effects of oxidation and weathering on char formation and coal combustion, in H.H. Schobert, K.D. Bartle, and L.J. Lynch, eds., Coal Science II: American Chemical Society, Symposium Series 461, p. 284-298.

Benedict, L.G., and W.F. Berry, 1966, Further applications of coal petrography, in R.F. Gould, ed., Coal science: American Chemical Society, Advances in Chemistry Series 55, p. 577-601.

Bennaceur, K., 2014, CO2 capture and sequestration, in T.M. Letcher, ed., Future energy, second edition: New York, Elsevier, p. 583-611.

Bensley, D.F., and J.C. Crelling, 1994, Presence of remanent cell structure in vitrinite and its influence on reflectance properties, in P.K. Mukhopadhyay and W.G. Dow, eds., Vitrinite reflectance as a maturity parameter: applications and limitations: Washington, D.C., American Chemical Society Symposium Series 570, p. 39-51.

Berggren, D., 1991, Measuring coal seam thicknesses with normal-lateral electric logs: Illinois State Geological Survey, Illinois Minerals 107, 26 p.Berggren, L.W., and G.A. Sanderson, 2001, Recent developments in the application of the §29 tax credit to coal seam gas: Tuscaloosa, Alabama, Proceedings, International Coalbed Methane Symposium, Paper 104, p. 257-269.Berkowitz, N., 1979, An introduction to coal technology: New York, Academic Press, 345 p.Berkowitz, N., 1979, An introduction to coal technology: New York, Academic Press, 345 p.Berkowitz, N., 1985, The chemistry of coal: New York, Elsevier, Coal Science and Technology, v. 7, 513 p.

Berkowitz, N., 1994, An introduction to coal technology: Academic Press, 398 p.Berkowitz, N., 1994, An introduction to coal technology: Academic Press, 398 p.Berryhill, L.R., and P. Averitt, 1951, Coking-coal deposits of the western United States: U.S. Geological Survey Circular 90, 20 p.Bertard, C., B. Bruyet, and J. Gunther, 1970, Determination of desorbable gas concentration of coal (Direct Method): International Journal of Rock Mechanics and Mining Science, v. 7, p. 43-65.Bertier, P., R. Swennen, B. Laenen, D. Lagrou, and R. Dreesen, 2006, Experimental identification of CO2-water-rock interactions caused by sequestration of CO2 in Westphalian and Buntsandstein sandstones of the Campine Basin (NE-Belgium): Journal of Geochemical Exploration v. 89, p. 10-14.Bertoli, O., A. Paul, Z. Casley, and D. Dunn, 2013, Geostatistical drillhole spacing analysis for coal resource classification in the Bowen Basin, Queensland: International Journal of Coal Geology, v. 112, p. 107-113.

Bertrand, P., 1984, Geochemical and petrographic characterization of humic coals considered as possible oil source rocks: Organic Geochemistry, v. 6, p. 481-488.Bertrand, P., 1984, Geochemical and petrographic characterization of humic coals considered as possible oil source rocks: Organic Geochemistry, v. 6, p. 481-488. (Ro vs. Tmax for coal)Bertrand, P., 1989, Microfacies and petroleum properties of coals as revealed by a study of North Sea Jurassic coals: International Journal of Coal Geology, v. 13, p. 575-595.

Bertrand, P., ed., 1991, Coal: formation, occurrence and related properties: Bulletin de la Societe Geologique de France, v. 162, p. 137-448.

Bertrand, P., J.-L. Pittion, and C. Bernaud, 1986, Fluorescence of sedimentary organic matter in relation to its chemical composition: Organic Geochemistry, v. 10, p. 641-647.Bertrand, P., J.-L. Pittion, and C. Bernaud, 1986, Fluorescence of sedimentary organic matter in relation to its chemical composition: Organic Geochemistry, v. 10, p. 641-647.

Bertrand, R., 1990, Correlations among the reflectances of vitrinite, chitinozoans, graptolites and scolecodonts: Organic Geochemistry, v. 15, p. 565-574.Bertrand, R., 1990, Correlations among the reflectances of vitrinite, chitinozoans, graptolites and scolecodonts: Organic Geochemistry, v. 15, p. 565-574.Bertrand, R., 1990, Maturation thermique et histoire de l’enfouissement et de la generation des hydrocarbures du bassin de l’archipel de Mingan et de l’ile d’ Anticosti, Canada: Canadian Journal of Earth Sciences, v. 27, p. 731-741.Bertrand, R., 1991, Maturation thermique des roches meres dans les bassins des basses-terres du Saint-Laurent et dans quelques buttes temoins au sud-est du bouclier canadien: International Journal of Coal Geology, v. 19, p. 359-383.

Bertrand, R., and M. Malo, 2001, Source rock analysis, thermal maturation and hydrocarbon generation in the Siluro-Devonian rocks of the Gaspé Belt basin, Canada: Bulletin of Canadian Petroleum Geology, v. 49, p. 238-261. (new calibration of collotelinite, chitinozoans, and solid bitumen)Bertrand, R., and M. Malo, 2001, Source rock analysis, thermal maturation and hydrocarbon generation in the Siluro-Devonian rocks of the Gaspé Belt basin, Canada: Bulletin of Canadian Petroleum Geology, v. 49, p. 238-261. (new calibration of collotelinite, chitinozoans, and solid bitumen)Bertrand, R., and M. Malo, 2001, Source rock analysis, thermal maturation and hydrocarbon generation in the Siluro-Devonian rocks of the Gaspé Belt basin, Canada: Bulletin of Canadian Petroleum Geology, v. 49, p. 238-261. (new calibration of collotelinite, chitinozoans, and solid bitumen)

Bertrand, R., and Y. Heroux, 1987, Chitinozoan, graptolite, and scolecodont reflectance as an alternative to vitrinite and pyrobitumen reflectance in Ordovician and Silurian strata, Anticosti Island, Quebec, Canada: AAPG Bulletin, v. 71, p. 951-957.Bertrand, R., and Y. Heroux, 1987, Chitinozoan, graptolite, and scolecodont reflectance as an alternative to vitrinite and pyrobitumen reflectance in Ordovician and Silurian strata, Anticosti Island, Quebec, Canada: AAPG Bulletin, v. 71, p. 951-957.Bertrand, R., D. Lavoie, and M. Fowler, 2003, Cambrian-Ordovician shales in the Humber zone: thermal maturation and source rock potential: Bulletin of Canadian Petroleum Geology, v. 51, p. 213-233.Bertrand, R., J.-C. Berube, Y. Heroux, and A. Achab, 1985, Petrographie du kerogene dans le paleozoique inferieur: methode de preparation et exemple d'application: Revue de l'Institut Francais du Petrole, v. 49, p. 155-167.Bertrand, R., J.-C., Berube, Y. Heroux, and A. Achab, 1985, Petrographie du kerogene dans le Paleozoique inferieur: methode de preparation et exemple d'application: Revue de l'Institut Francais du Petrole, v. 40, p. 155-167.Beskrovnyi, N.S., I.S. Gol’dberg, K.K. Makarov, V.S. Sobolev, and S.D. Taliev, 1975, Natural solid bitumens in the USSR — an important raw material reserve for the national economy: Geologiia Nefti I Gaza, no. 4, p. 14-20.Bhangare, R.C., P.Y. Ajmal, S.K. Sahu, G.G. Pandit, and V.D. Puranik, 2011, Distribution of trace elements in coal and combustion residues from five thermal power plants in India: International Journal of Coal Geology, v. 86, p. 349-356.Bhangare, R.C., P.Y. Ajmal, S.K. Sahu, G.G. Pandit, and V.D. Puranik, 2011, Distribution of trace elements in coal and combustion residues from five thermal power plants in India: International Journal of Coal Geology, v. 86, p. 349-356.

Berkowitz, N., 1994, An introduction to coal technology, 2nd ed.: San Diego, Academic Press, 398 p.

Bertrand, P., 1984, Geochemical and petrographic characterization of humic coals considered as possible oil source rocks, in P.A. Schenck, J.W. de Leeuw, and G.W.M. Lijmbach, eds., Advances in organic geochemistry 1983: Organic Geochemistry, v. 6, p. 481-488.

Bertrand, P., E. Lallier-Verges, L. Martinez, B. Pradier, P. Tremblay, A. Huc, R. Jouhannel, and J.P. Tricart, 1990, Examples of spatial relationships between organic matter and mineral groundmass in the microstructure of the organic-rich Dorset Formation rocks, Great Britain, in B. Durand and F. Behar, eds., Advances in organic geochemistry 1989, part II, molecular geochemistry: Organic Geochemistry, v. 16, p. 661-675.

Bertrand, P., F. Behar, and B. Durand, 1986, Composition of potential oil from humic coals in relation to their petrographic nature, in D. Leythaeuser and J. Rullkotter, eds., Advances in organic geochemistry 1985: Organic Geochemistry, v. 10, p. 601-608.

Bertrand, P., L. Martinez, and B. Pradier, 1987, Petrologic study of primary migration by hydrous pyrolysis, in Migration of hydrocarbons in sedimentary basins: Paris, Editions Technip, Collection Colloques et Seminaires, v. 45, p. 633-647.

Bertrand, R., 1993, Standardization of solid bitumen reflectance to vitrinite in some Paleozoic sequences of Canada, in F. Goodarzi and R.W. Macqueen, eds., Geochemistry and petrology of bitumen with respect to hydrocarbon generation and mineralization: Energy Sources, v. 15, p. 269-287.Bertrand, R., 1993, Standardization of solid bitumen reflectance to vitrinite in some Paleozoic sequences of Canada, in F. Goodarzi and R.W. Macqueen, eds., Geochemistry and petrology of bitumen with respect to hydrocarbon generation and mineralization: Energy Sources, v. 15, p. 269-287.Bertrand, R., 1993, Standardization of solid bitumen reflectance to vitrinite in some Paleozoic sequences of Canada, in F. Goodarzi and R.W. Macqueen, eds., Geochemistry and petrology of bitumen with respect to hydrocarbon generation and mineralization: Energy Sources, v. 15, p. 269-287.

Bertrand, R., and M. Malo, 2012, Dispersed organic matter reflectance and thermal maturation in four hydrocarbon exploration wells in the Hudson Bay Basin: regional implications: Geological Survey of Canada, Open File 7066, 52 p. ftp://ftp2.cits.rncan.gc.ca/pub/geott/ess_pubs/289/289709/of_7066.pdf

Bhaskaran, R., and U.P. Singh, 2000, Indian coalbed methane: Mintech, v. 21, no. 2, p. 13-20.Bhowmik, S., and P. Dutta, 2013, Adsorption rate characteristics of methane and CO2 in coal samples from Raniganj and Jharia coalfields of India: International Journal of Coal Geology, v. 113, p. 50-59.Bialecka, B., 2008, Estimation of coal reserves for UCG in the Upper Silesian coal basin, Poland: Natural Resources Research, v. 17, no. 1, p. 21-28.Białecka, B., 2008, Estimation of coal reserves for UCG in the Upper Silesian coal basin, Poland: Natural Resources Research, v. 17, no. 1, p. 21-28.

Bibler, C.J., J.S. Marshall, and R.C. Pilcher, 1998, Status of worldwide coal mine methane emissions and use: International Journal of Coal Geology, v. 35, p. 283-310.Bibler, C.J., J.S. Marshall, and R.C. Pilcher, 1998, Status of worldwide coal mine methane emissions and use: International Journal of Coal Geology, v. 35, p. 283-310.Bickle, M., and N. Kampman, 2013, Lessons in carbon storage from geological analogues: Geology, v. 41, p. 525-526.Bielowicz, B., 2012, A new technological classification of low-rank coal on the basis of Polish deposits: Fuel, v. 96, p. 497-510.Bielowicz, B., 2012, A new technological classification of low-rank coal on the basis of Polish deposits: Fuel, v. 96, p. 497-510.Bielowicz, B., 2013, Petrographic composition of Polish lignite and its possible use in a fluidized bed gasification process: International Journal of Coal Geology, v. 116-117, p. 236-246.Bielowicz, B., 2013, Relationship between random reflectance of ulminite B/collotelinite and technological parameters of Polish low-rank coal: Fuel, v. 111, p. 229-238.Biglarbigi, K., H. Mohan, and J. Killen, 2009, Oil shale—1. US, world possess rich resource base: Oil & Gas Journal, v. 107.3, p. 56-61.Biglarbigi, K., H. Mohan, M. Carolus, and J. Killen, 2009, Oil shale—3. Analytic approach estimates oil shale development economics: Oil & Gas Journal, v. 107.5, p. 48-53.Biglarbigi, K., J. Killen, and M. Carolus, 2010, Analysis sees potential for shale oil: American Oil & Gas Reporter, v. 53, no. 2, p. 62-67.Birdwell, J.E., T.J. Mercier, R.C. Johnson, and M.E. Brownfield, 2013, In-place oil shale resources examined by grade in the major basins of the Green River Formation, Colorado, Utah, and Wyoming: U.S. Geological Survey, Fact Sheet 2012-3145, 3 p.Birk, D., 1989, Coal minerals: quantitative and descriptive SEM-EDX analysis: Journal of Coal Quality, v. 8, p. 55-62.Birk, D., 1990, Quantitative coal mineralogy of the Sydney Coalfield, Nova Scotia, Canada, by scanning electron microscopy, computerized image analysis, and energy-dispersive x-ray spectrometry: Canadian Journal of Earth Sciences, v. 27, p. 163-179.Bishop, A.N., and G.D. Abbott, 1994, Vitrinite reflectance and molecular geochemistry of Jurassic sediments: the influence of heating by Tertiary dykes (northwest Scotland): Organic Geochemistry, v. 22, p. 165-177.Bishop, A.N., and R.P. Philp, 1994, Potential for amorphous kerogen formation via adsorption of organic material at mineral surfaces: Energy & Fuels, v. 8, p. 1494-1497.

Blake, W.P., 1885, Uintahite, a new variety of asphaltum from the Uinta Mountains, Utah: Engineering and Mining Journal, v. 40, p. 431.Blake, W.P., 1889, Wurtzilite: Engineering and Mining Journal, v. 48, p. 542.Blake, W.P., 1890, Uintaite, albertite, grahamite, and asphaltum described and compared, with observations on bitumen and its compounds: Transactions of the American Institute of Mining Engineers, v. 18, p. 563-582.Blandón, A., and G. Gorin, 2013, Combining palynofacies and petrography in the study of sub-bituminous tropical coals: A case history from Lower Tertiary coals in Colombia: International Journal of Coal Geology, v. 108, p. 65-82.Blandon, A., N. Parra, G.E. Gorin, and F. Arango, 2008, Adapting palynological preparation methods in subbituminous and bituminous coals from Colombia to improve palynofacies and hydrocarbon source rock evaluations: International Journal of Coal Geology, v. 73, p. 99-114.Blandon, A., N. Parra, G.E. Gorin, and F. Arango, 2008, Adapting palynological preparation methods in subbituminous and bituminous coals from Colombia to improve palynofacies and hydrocarbon source rock evaluations: International Journal of Coal Geology, v. 73, p. 99-114.Blaustein, B.D., and others, eds., 1981, New approaches in coal chemistry: Washington D.C., American Chemical Society Symposium Series 169, 462 p.Blissett, R.S., and N.A. Rowson, 2012, A review of the multi-component utilisation of coal fly ash: Fuel, v. 97, p. 1-23.Blissett, R.S., N. Smalley, and N.A. Rowson, 2014, An investigation into six coal fly ashes from the United Kingdom and Poland to evaluate rare earth element content: Fuel, v. 119, p. 236-239.

Boak, J., 2009, One million barrels of shale oil per day: How and how soon?: Oil Shale Symposium, Tallinn, Estonia, June 2009.

Bibler, C., and P. Carothers, 2000, Overview of coal mine gas use technologies: Second International Methane Mitigation Conference, Novosibirsk, Russia, June 2000, 8 p. (available at Raven Ridge web site: www.ravenridge.com)Bibler, C., and P. Carothers, 2000, Overview of coal mine gas use technologies: Second International Methane Mitigation Conference, Novosibirsk, Russia, June 2000, 8 p. (available at Raven Ridge web site: www.ravenridge.com)

Bjørlykke, K., 2010, Source rocks and petroleum geochemistry, in Petroleum geoscience: From sedimentary environments to rock physics: New York, Springer-Verlag, p. 339-348.Bjoroy, M., and J.O. Vigran, 1980, Geochemical study of the organic matter in outcrop samples from Agardhfjellet, Spitsbergen, in A.G. Douglas and J.R. Maxwell, eds., Advances in organic geochemistry 1979: New York, Pergamon Press, Physics and Chemistry of the Earth, v. 12, p. 141-147.Bjoroy, M., K. Hall, and J.O. Vigran, 1980, An organic geochemical study of Mesozoic shales from Andoya, North Norway, in A.G. Douglas and J.R. Maxwell, eds., Advances in organic geochemistry 1979: New York, Pergamon Press, Physics and Chemistry of the Earth v. 12, p. 77-91.Blackburn, K.B., and B.N. Temperley, 1936, Botryococcus and the algal coals: Royal Society Edinburgh Transactions, v. 58, p. 841-868.Blackburn, K.B., and B.N. Temperley, 1936, Botryococcus and the algal coals: Trans. Royal Soc. Edinburgh, v. 58, p. 841-870.Blackwell, D.D., and J.L. Steele, 1989, Thermal conductivity of sedimentary rocks: measurement and significance, in N.D. Naeser and T.H. McCulloh, eds., Thermal history of sedimentary basins: New York, Springer-Verlag, p. 13-36.

Boak, J., 2008, Estimate of carbon dioxide production for in-situ production of shale oil from the Green River Formation in western Colorado: Proceedings of the 27th Oil Shale Symposium, Colorado Energy Research Institute Document 2008-1, Colorado School of Mines, Golden, CO (CD-ROM) http://www.ceri-mines.org/oilshaleresearch.htm

Boak, J., 2014, Shale-hosted hydrocarbons and hydraulic fracturing, in T.M. Letcher, ed., Future energy, second edition: New York, Elsevier, p. 117-143.Boak, J., and E. Mattson, 2010, Water use for in-situ production of oil from oil shale: Proceedings of the 29 th Oil Shale Symposium, Colorado School of Mines, Golden, CO (CD-ROM)Boardman, E.L., and J.H. Rippon, 1997, Coalbed methane migration in and around fault zones, in R. Gayer and J. Pesek, eds., European coal geology and technology: London, Geological Society Special Publication 125, p. 391-408.

Bőcker, J., R. Littke, C. Hartkopf-Frőder, K. Jasper, and J. Schwarzbauer, 2013, Organic geochemistry of Duckmantian (Pennsylvanian) coals from the Ruhr Basin, western Germany: International Journal of Coal Geology, v. 107, p. 112-126.Bocong, G.G., W. Shengming, W. Lisheng, and Q. Zongda, 1986, Coal powder injection in blast furnaces of Shoudu Iron and Steel Company: Iron and Steel Society Conference Proceedings, v. 45, p. 501-507.

Boden, T., 2014, Utah still supplying gilsonite to the world after 125 years of mining: Utah Geological Survey, Survey Notes, v. 46, no. 1, p. 4-5.Boden, T., and B.T. Tripp, 2012, Gilsonite veins of the Uinta Basin, Utah: Utah Geological Survey Special Study 141, 50 p.Bohacs, K., and J. Suter, 1997, Sequence stratigraphic distribution of coaly rocks: fundamental controls and paralic examples: AAPG Bulletin, v. 81, p. 1612-1639.Bohor, B.F., and D.M. Triplehorn, 1993, Tonsteins: altered volcanic-ash layers in coal-bearing sequences: GSA Special Paper 285, 56 p.Bojesen-Koefoed, J.A., H.I. Petersen, F. Surlyk, and H. Vosgerau, 1997, Organic petrography and geochemistry of inertinite-rich mudstones, Jakobsstigen Formation, Upper Jurassic, northeast Greenland: indications of forest fires and variations in relative sea-level: International Journal of Coal Geology, v. 34, p. 345-370.

Bonnett, R., 1996, Porphyrins in coal: International Journal of Coal Geology, v. 32, p. 137-149.

Boreham, C.J., and T.G. Powell, 1987, Sources and preservation of organic matter in the Cretaceous Toolebuc Formation, eastern Australia: Organic Geochemistry, v. 11, p. 433-449. (origin of bituminite)

Boreham, C.J., B. Horsfield, and H.J. Schenk, 1999, Predicting the quantities of oil and gas generated from Australian Permian coals, Bowen Basin using pyrolytic methods: Marine and Petroleum Geology, v. 16, p. 165-188.Boreham, C.J., J.E. Blevin, A.P. Radlinski, and K.R. Trigg, 2003, Coal as a source of oil and gas: a case study from the Bass Basin, Australia: The Australian Petroleum Production and Exploration Association Journal 2003, p. 117-148.Boreham, C.J., S.D. Golding, and M. Glikson, 2001, Reply to Comment of Smith and Pallasser on "Factors controlling the origin of gas in Australian Bowen basin coals": Organic Geochemistry, v. 32, p. 207-210.Boreham, C.J., S.G. Golding, and M. Glikson, 1998, Factors controlling the origin of gas in Australian Bowen basin coals: Organic Geochemistry, v. 29, p. 347-362.Borrego, A.G., and A.J. Martin, 2010, Variation in the structure of anthracite at a fast heating rate as determined by its optical properties: an example of oxy-combustion conditions in a drop tube reactor: International Journal of Coal Geology, v. 81, p. 301-308.Borrego, A.G., C.V. Araujo, A. Balke, B. Cardott, A.C. Cook, P. David, D. Flores, M. Hámor-Vidó, W. Hiltmann, W. Kalkreuth, J. Koch, C.J. Kommeren, J. Kus, B. Ligouis, M. Marques, J.G. Mendoça Filho, M. Misz, L. Oliveira, W. Pickel, K. Reimer, P. Ranasinghe, I. Suárez-Ruiz, and A. Vieth, 2006, Influence of particle and surface quality on the vitrinite reflectance of dispersed organic matter: Comparative exercise using data from the qualifying system for reflectance analysis working group of ICCP: International Journal of Coal Geology, v. 68, p. 151-170.Borrego, A.G., D. Alvarez, and R. Menendez, 1997, Effects of inertinite content in coal on char structure and combustion: Energy Fuels, v. 11, p. 702-708.Bosse, R., H. Heidecke, and H.H. Oelert, 1991, Liquefaction potential of South African torbanite coal, II. Coprocessing in blended solvent and technical petroleum vacuum residue: Erdöl und Kohle-Erdgas-Petrochemie, v. 44, no. 11, p. 418-420.Bostic, J., L. Brady, M. Howes, R.R. Burchett, and B.S. Pierce, 1993, Investigation of the coal properties and the potential for coal-bed methane in the Forest City basin: USGS Open-File Report OF 93-0576, 44 p.

Bostick, N.H., 2011, Measured reflectance suppressed by thin-film interference of crude oil smeared on glass—as on vitrinite in coal or petroliferous rocks: TSOP Newsletter, v. 28, no. 2, p. 12-15.Bostick, N.H., 2011, Measured reflectance suppressed by thin-film interference of crude oil smeared on glass—as on vitrinite in coal or petroliferous rocks: TSOP Newsletter, v. 28, no. 2, p. 12-15.Bostick, N.H., and B. Alpern, 1977, Principles of sampling, preparation and constituent selection for microphotometry in measurement of maturation of sedimentary organic matter: Journal of Microscopy, v. 109, pt. 1, p. 41-47.Bostick, N.H., and C.P. Nicksic, 1975, Bibliography and index of coal and dispersed organic matter in sedimentary rocks: petrography, catagenesis, relation to petroleum and natural gas, and geochemistry: Illinois State Geological Survey Illinois Petroleum 108, 92 p.

Bostick, N.H., and T.A. Daws, 1994, Relationships between data from Rock-Eval pyrolysis and proximate, ultimate, petrographic, and physical analyses of 142 diverse U.S. coal samples: Organic Geochemistry, v. 21, p. 35-49.Bostick, N.H., and T.A. Daws, 1994, Relationships between data from Rock-Eval pyrolysis and proximate, ultimate, petrographic, and physical analyses of 142 diverse U.S. coal samples: Organic Geochemistry, v. 21, p. 35-49.Bostick, N.H., W.J. Betterton, H.J. Gluskoter, and M.N. Islam, 1991, Petrography of Permian "Gondwana" coals from boreholes in northwestern Bangladesh, based on semiautomated reflectance scanning: Organic Geochemistry, v. 17, p. 399-413.

Boudou, J.-P., J. Espitalié, J. Bimer, and P. Salbut, 1994, Oxygen groups and oil suppression during coal pyrolysis: Energy and Fuels, v. 8, p. 972-977.

Bourrat, X., A. Oberlin, and J.C. Excalier, 1986, Microtexture and structure of semi-cokes and cokes: Fuel, v. 65, p. 1490.

Bodden, W.R., III, and R. Ehrlich, 1998, Permeability of coals and characteristics of desorption tests: implications for coalbed methane production, in R.M. Flores, ed., Coalbed methane: from coal-mine outbursts to a gas resource: International Journal of Coal Geology, v. 35, p. 333-347.

Bond, L.O., R.P. Alger, and A.W. Schmidt, 1986, Well log applications in coal mining and rock mechanics, in D.J. Buchanan and L.J. Jackson, eds., Coal geophysics: Tulsa, Society of Exploration Geophysicists, Geophysics Reprint Series 6, p. 28-35.

Bordelon, N.J., 2006, Coalbed methane production potential in the Hartshorne Formation (Oklahoma)(abstract): Gulf Coast Association of Geological Societies, Annual Meeting, Lafayette, LA, September 25-27, 2006, abstracts. (http://www.gcags2006.com/ABSTRACTS/shale.html) Bordenave, M.L., J. Espitalie, J. Leplat, J.L. Oudin, and M. Vandenbroucke, 1993, Screening techniques for source rock evaluation, in M.L. Bordenave, ed., Applied petroleum geochemistry: Paris, Editions Technip, p. 217-278. (Rock-Eval, p. 237-255)

Boreham, C.J., and T.G. Powell, 1993, Petroleum source rock potential of coal and associated sediments: qualitative and quantitative aspects, in B.E. Law and D.D. Rice, eds., Hydrocarbons from coal: AAPG Studies in Geology 38, p. 133-157.

Bostick, N.H., 1979, Microscopic measurement of the level of catagenesis of solid organic matter in sedimentary rocks to aid exploration for petroleum and to determine former burial temperatures -- a review, in P.A. Scholle and P.R. Schluger, eds., Aspects of diagenesis: SEPM Special Publication 26, p. 17-43.Bostick, N.H., 1979, Microscopic measurement of the level of catagenesis of solid organic matter in sedimentary rocks to aid exploration for petroleum and to determine former burial temperatures - a review, in P.A. Scholle and P.R. Schluger, eds., Aspects of diagenesis: SEPM Special Publication 26, p. 17-43.Bostick, N.H., 1979, Microscopic measurement of the level of catagenesis of solid organic matter in sedimentary rocks to aid exploration for petroleum and to determine former burial temperatures -- a review, in P.A. Scholle, and P.R. Schluger, eds., Aspects of Diagenesis: S.E.P.M. Special Publication 26, p. 17-43.

Bostick, N.H., and J.L. Clayton, 1986, Organic petrology applied to study of thermal history and organic geochemistry of igneous contact zones and ore deposits in sedimentary rock, in W.E. Dean, ed., Organics and ore deposits: Proceedings of the Denver Region Exploration Geologists Society Symposium, p. 33-55.Bostick, N.H., and J.N. Foster, 1975, Comparison of vitrinite reflectance in coal seams and in kerogen of sandstones, shales, and limestones in the same part of a sedimentary section, in B. Alpern, ed., Petrographie de la matiere organique des sediments, relations avec la paleotemperature et le potentiel petrolier: Paris, CNRS, p. 13-25.Bostick, N.H., and J.N. Foster, 1975, Comparison of vitrinite reflectance in coal seams and in kerogen of sandstones, shales, and limestones in the same part of a sedimentary section, in B. Alpern, eds., Petrographie de la matiere organique des sediments, relations avec la paleotemperature et le potentiel petrolier: Paris, CNRS, p. 13-25.Bostick, N.H., and M.J. Pawlewicz, 1984, Paleotemperatures based on vitrinite reflectance of shales and limestones in igneous dike aureoles in the Upper Cretaceous Pierre Shale, Walsenburg, Colorado, in J. Woodward, F.F. Meissner, and J.L. Clayton, eds., Hydrocarbon source rocks of the greater Rocky Mountain Region: Denver, CO, Rocky Mountain Association of Geologists, p. 387-392.

Boudou, J.-P., 1990, Coal desulfurization by programmed-temperature pyrolysis and oxidation, in W.L. Orr and C.M. White, eds., Geochemistry of sulfur in fossil fuels: Washington, D.C., American Chemical Society Symposium Series 429, p. 345-364.

Boulter, M.C., 1994, An approach to a standard terminology for palynodebris, in A. Traverse, ed., Sedimentation of organic particles: Cambridge University Press, p. 199-216.

Bouska, V., 1981, Geochemistry of coal: New York, Elsevier Scientific Publishing Company, Coal Science and Technology, v. 1, 284 p.Boussafir, M., F. Gelin, E. Lallier-Verges, S. Derenne, P. Bertrand, and C. Largeau, 1995, Electron microscopy and pyrolysis of kerogens from the Kimmeridge Clay Formation, UK: source organisms, preservation processes, and origin of microcycles: Geochimica et Cosmochimica Acta, v. 59, p. 3731-3747.Bowen, B.B., R.I. Ochoa, N.D. Wilkens, J. Brophy, T.R. Lovell, N. Fischietto, C.R. Medina, and J.A. Rupp, 2011, Depositional and diagenetic variability within the Cambrian Mount Simon Sandstone: Implications for carbon dioxide sequestration: Environmental Geosciences Journal, v. 18, no. 2.Bowersox, J.R., and M.J. Lynch, 2010, Carbon storage tests by the Kentucky Geological Survey in western Kentucky—ownership, access, and liability issues: UK Center for Applied Energy Research, Energeia, v. 21, no. 3, p. 1-3.Boyapati, E., W.A. Oates, N.T. Moxon, J.C. Day, and C.K. Baker, 1984, The weathering characteristics of coking coals: Fuel, v. 63, p. 551-556.Boyce, C.K., M. Abrecht, D. Zhou, and P.U.P.A. Gilbert, 2010, X-ray photoelectron emission spectromicroscopic analysis of arborescent lycopsid cell wall composition and Carboniferous coal ball preservation: International Journal of Coal Geology, v. 83, p. 146-153.Boyd, R.J., 2002, The partitioning behaviour of boron from tourmaline during ashing of coal: International Journal of Coal Geology, v. 53, p. 43-54.Boyer, C.M., II, 1989, The coalbed methane resource and the mechanisms of gas production: GRI Topical Report GRI 89/0266, 115 p.

Boyer, C.M., II, and S.R. Reeves, 1989, A strategy for coalbed methane production development part III: production operations: Proceedings of the 1989 Coalbed Methane Symposium, paper 8913, p. 19-27.Boysen, J.E., and D.B. Boysen, 2003, Selected coal bed methane produced water management strategies and associated technical and economic issues (abstract): AAPG Annual Convention Official Program, v. 12, p. A19.

Bradfield, J.J.C., 1943, Oil from coal: Qld. Geogr. J., p. 47-52.Bradley, W.H., 1931, Origin and microfossils of the oil shale of the Green River Formation of Colorado and Utah: U.S. Geological Survey Professional Paper 168.Bradshaw, J., and others, 2007, CO2 storage capacity estimation: issues and development of standards: International Journal of Greenhouse Gas Control, v. 1, p. 62-68.

Brady, L.L., 2000, Kansas coal distribution, resources, and potential for coalbed methane: The Compass of Sigma Gamma Epsilon, v. 75, nos. 2 & 3, p. 122-133.

Bragg, L.J., J.K. Oman, S.J. Tewalt, C.J. Oman, N.H. Rega, P.M. Washington, and R.B. Finkelman, 1998, U.S. Geological Survey coal quality (COALQUAL) database: U.S. Geological Survey Open-File Report 97-134, CD-ROM. http://pubs.usgs.gov/of/1997/of97-134/ http://energy.er.usgs.gov/products/databases/CoalQual/index.htm

Braggio Morucchio, G., 1987, On the autofluorescence of some vascular plants pollen and spores: Pollen et Spores, v. 29, p. 329-337.Brake, D.E., 2009, Airborne technology identifies, maps CBM seeps: Hart’s E&P, v. 62, no. 12, p. 63.Brasier, M.D., 1980, Microfossils: Boston, George Allen & Unwin, 193 p.

Breit, G.N., and R.B. Finkelman, eds., 1998, Characterization of coal and coal combustion products from a coal-burning power plant; preliminary report and results of analyses: U.S. Geological Survey Open-File Report 98-0342, 101 p.Breland, F.C., Jr. and C.J. John, 2002, Regional trends and exploration potential for coal bed methane in Louisiana (abstract): AAPG Annual Convention Official Program, v. 11, p. A22-23.

Breland, F.C., Jr., 2005, A brief discussion of coalbed methane (CBM) in Louisiana: Society of Independent Professional Earth Scientists, SIPES Quarterly, v. 42, no. 1, p. 1, 8-9.

Brendow, K., 2003, Global oil shale issues and perspectives: Oil Shale, v. 20, p. 81-92.Brennan, S.T., and R.C. Burruss, 2006, Specific storage volumes: a useful tool for CO2 storage capacity assessment: Natural Resources Research, v. 15, p. 165-182.

Brinck, E.L., J.I. Drever, and C.D. Frost, 2008, The geochemical evolution of water coproduced with coalbed natural gas in the Powder River Basin, Wyoming: Environmental Geosciences, v. 15, no. 4, p. 153-171.Broadbent, S.R., and A.J. Shaw, 1955, Reflectance of coal: Fuel, v. 34, p. 385-403.Broadhead, G.C., 1877, Bitumen, asphaltum, petroleum, pyroschists, and certain other solid hydrocarbons: The Western Review of Science and Industry, v. 1, p. 209-224.Brodzki, D., A.A. Akar, G.D. Mariadassou, C.Z. Li, B. Xu, and R. Kandiyoti, 1994, Liquefaction of coal and maceral concentrates in a stirred micro-autoclave and a flowing-solvent reactor: Fuel, v. 73, p. 1331fBromhal, G.S., W.N. Sams, S. Jikich, T. Ertekin, and D.H. Smith, 2005, Simulation of CO2 sequestration in coal beds: the effects of sorption isotherms: Chemical Geology, v. 217, p. 201-211.

Boyer, C.M., II, and B. Quingzhao, 1998, Methodology of coalbed methane resource assessment, in R.M. Flores, ed., Coalbed methane: from coal-mine outbursts to a gas resource: International Journal of Coal Geology, v. 35, p. 349-368.

Bracmort, K., J.L. Ramseur, J.E. McCarthy, P. Folger, and D.J. Marples, 2010, Methane capture: options for greenhouse gas emission reduction: Congressional Research Service, R40813, 24 p. http://ncseonline.org/NLE/CRSreports/10Jun/R40813.pdf

Brady, L. L., and K.D. Newell, 2004, Kansas coal and coalbed methane—an overview, in Overview of coal and coalbed methane in the Cherokee basin, northeast Oklahoma: Fieldtrip guidebook for the First Coalbed Methane Symposium, Tulsa, Oklahoma, November, 9, 2004, Oklahoma Geological Survey and Kansas Geological Survey, p. 97-116. (Available as Kansas Geological Survey Open-file report 2004-49).Brady, L.L., 1997, Kansas coal resources and their potential for coalbed methane, in G. McMahan, ed., Transactions of the 1997 AAPG Mid-Continent Section Meeting: Oklahoma City Geological Society, p. 150-163.

Brady, L.L., 2002, Eastern Kansas—some considerations for coalbed methane in Proceedings of 2002 Coalbed Methane Symposium: Rocky Mountain Association of Geologists, Denver, Colorado, June 19, 2002, 5p.

Bragg, L.J., J.K. Oman, S.J. Tewalt, C.L. Oman, N.H. Rega, P.M. Washington, and R.B. Finkelman, 1994, U.S. Geological Survey coal quality (COALQUAL) database: U.S. Geological Survey Open-File Report 94-205. http://pubs.er.usgs.gov/publication/ofr94205

Breger, I.A., 1963, Origin and classification of naturally occurring carbonaceous substances, in I.A. Breger, ed., Organic Geochemistry: The Macmillan Company, A Pergamon Press Book, Earth Science Series, Monograph 16, p. 50-86.Breger, I.A., P. Zubovic, J.C. Chandler, and D.T. Ligon, Jr., 1976, Effects of oxidation on the chemical structure and properties of coals, in C.J. Smith, compiler, Proceedings of the coal agglomeration and conversion symposium: Morgantown, WV, West Virginia Geological and Economic Survey, p. 1.

Breland, F.C., Jr., 2004, Coalbed methane potential in Louisiana, in P.D. Warwick, ed., Selected presentations on coal-bed gas in the eastern United States: U.S. Geological Survey Open File Report 2004-1273, p. 27-35. (http://pubs.usgs.gov/of/2004/1273/)

Breland, F.C., Jr., and P.D. Warwick, 2004, Coalbed methane (CBM) activity in Louisiana, in Coalbed methane in the Gulf Coast: Gulf Coast Association of Geological Societies/Gulf Coast Section SEPM, 54 th Annual Convention, San Antonio, TX, Short Course No. 3.

Brennan, S.T., R.C. Burruss, M.D. Merrill, P.A. Freeman, and L.F. Ruppert, 2010, A probabilistic assessment methodology for the evaluation of geologic carbon dioxide storage: U.S. Geological Survey Open-File Report 2010-1127, 31 p. http://pubs.usgs.gov/of/2010/1127/ofr2010-1127.pdfBrenner, D., 1984, Microscopic IR spectroscopy of coals, in R.E. Winans and J.C. Crelling, eds., Chemistry and Characterization of Coal Macerals: Washington, American Chemical Society, ACS Symposium Series 252, p. 48-64.

Brooks, J., 1981, Organic maturation of sedimentary organic matter and petroleum exploration: a review, in J. Brooks, ed., Organic maturation studies and fossil fuel exploration: San Francisco, Academic Press, p. 1-37.

Brooks, J.D., 1970, The use of coals as indicators of the occurrence of oil and gas: APEA Journal, v. 10, p. 35-40.Brooks, J.D., and J.W. Smith, 1967, The diagenesis of plant lipids during the formation of coal, petroleum and natural gas. I. changes in the n-paraffin hydrocarbons: Geochimica et Cosmochimica Acta, v. 31, p. 2389-2397.Brooks, J.D., and J.W. Smith, 1969, The diagenesis of plant lipids during the formation of coal, petroleum and natural gas. II. coalification and the formation of oil and gas in the Gippsland basin: Geochimica et Cosmochimica Acta, v. 33, p. 1183-1194.Brooks, J.D., W.R. Hesp, and D. Rigby, 1971, The natural conversion of oil to gas in sediments in the Cooper basin: APEA Journal, v. 11, p. 121-125.Brooks, K., N. Svanas, and D. Glasser, 1988, Evaluating the risk of spontaneous combustion in coal stockpiles: Fuel, v. 67, p. 651-656.

Brown, A., 2011, Identification of source carbon for microbial methane in unconventional gas reservoirs: AAPG Bulletin, v. 95, p. 1321-1338.Brown, C.A., 2008, Palynological techniques, second edition, J.B. Riding and S. Warny, eds.: Dallas, American Association of Stratigraphic Palynologists Foundation, 137 p.Brown, D., 2007, CO2 answers are as elusive as CO2; capture, costs part of equation: AAPG Explorer, v. 28, no. 8, p. 14-18.

Brown, H.R., A.C. Cook, and G.H. Taylor, 1963, Variations in the properties of vitrinite in isometamorphic coal: Fuel, v. 43, p. 111-124.Brown, H.R., A.C. Cook, and G.H. Taylor, 1964, Variations in the properties of vitrinite in isometamorphic coal: Fuel, v. 43, p. 111-124.Brown, H.R., A.C. Cook, and G.H. Taylor, 1964, Variations in the properties of vitrinite in isometamorphic coal: Fuel, v. 43, p. 111-124.Brown, H.R., G.H. Taylor, and A.C. Cook, 1964, Prediction of coke strength from the rank and petrographic composition of Australian coals: Fuel, v. 43, p. 43-54.Brown, K., C.F.K. Diessel, M. Wolf, and E. Wolf-Fischer, 1985, The fluorescence properties of Carboniferous and Permian coking coals: Oxford, Pergamon Press, Proceedings of the International Conference on Coal Science, p. 649-652.Brown, K., D.A. Casey, J.R. Enever, R.A. Facer, and K. Wright, 1996, New South Wales coal seam methane potential: Geological Survey of New South Wales, Petroleum Bulletin 2, 96 p.Brown, P.J., W.J. Haskett, and P. Leach, 2006, Risk analysis approach helping operators see the light in unconventional plays: The American Oil & Gas Reporter, v. 49, no. 3, p. 84-93.

Brownfield, M.E., R.H. Affolter, G.D. Stricker, and R.T. Hildebrand, 1995, High chromium contents in Tertiary coal deposits of northwestern Washington—a key to their depositional history: International Journal of Coal Geology, v. 27, p. 153-169.Brownfield, M.E., R.H. Affolter, J.D. Cathcart, S.Y. Johnson, I.K. Brownfield, and C.A. Rice, 2005, Geologic setting and characterization of coals and the modes of occurrence of selected elements from the Franklin coal zone, Puget Group, John Henry No. 1 mine, King County, Washington, USA: International Journal of Coal Geology, v. 63, p. 247-275.Browning, J.S., 1961, Heavy liquids and procedures for laboratory separation of minerals: U.S. Bureau of Mines Information Circular 8007, 14 p.Bruening, F.A., and A.D. Cohen, 2005, Measuring surface properties and oxidation of coal macerals using the atomic force microscope: International Journal of Coal Geology, v. 63, p. 195-204.Bruening, F.A., and A.D. Cohen, 2005, Measuring surface properties and oxidation of coal macerals using the atomic force microscope: International Journal of Coal Geology, v. 63, p. 195-204.

Brüning, M., H. Sahling, I.R. MacDonald, F. Ding, and G. Bohrmann, 2010, Origin, distribution, and alteration of asphalts at Chapopote Knoll, southern Gulf of Mexico: Marine and Petroleum Geology, v. 27, p. 1093-1106.

Bryant, V.M., Jr., and J.H. Wrenn, eds., 1998, New developments in palynomorph sampling, extraction and analysis: American Association of Stratigraphic Palynologists Contributions Series, v. 33, 155 p.Buchanan, D.J., and L.J. Jackson, eds., 1986, Coal geophysics: Tulsa, Society of Exploration Geophysicists, Geophysics Reprint Series 6, 466 p.

Buchardt, B., and M.D. Lewan, 1990, Reflectance of vitrinite-like macerals as a thermal maturity index for Cambrian-Ordovician Alum Shale, southern Scandinavia: AAPG Bulletin, v. 74, p. 394-406.Buchardt, B., and M.D. Lewan, 1990, Reflectance of vitrinite-like macerals as a thermal maturity index for Cambrian-Ordovician Alum Shale, southern Scandinavia: AAPG Bulletin, v. 74, p. 394-406.Buchardt, B., and M.D. Lewan, 1990, Reflectance of vitrinite-like macerals as a thermal maturity index for Cambrian-Ordovician Alum Shale, southern Scandinavia: AAPG Bulletin, v. 74, p. 394-406.Buick, R., B. Rasmussen, and B. Krapez, 1998, Archaen oil: evidence for extensive hydrocarbon generation and migration 2.5–3.5 Ga: AAPG Bulletin, v. 82, p. 50-69.

Bujak, J.P., M.S. Barss, and G.L. Williams, 1977, Offshore east Canada's organic type and color and hydrocarbon potential, part I: Oil and Gas Journal, v. 75, no. 15, p. 198-202.

Brooks, J., C. Cornford, and R. Archer, 1987, The role of hydrocarbon source rocks in petroleum exploration, in J. Brooks and A.J. Fleet, eds., Marine petroleum source rocks: Geological Society Special Publication 26, p. 17-46.

Brosse, E., and A.Y. Huc, 1986, Organic parameters as indicators of thermal evolution in the Viking Graben, in J. Burrus, ed., Thermal modeling in sedimentary basins: Paris, Editions Technip, Collection Colloques et Seminaires, v. 44, p. 517-530. (use of Tmax, p. 523-528)

Brown, D., 2008, Sequestration faces variety of hurdles; EOR a rational starting point: AAPG Explorer, v. 29, no. 9, p. 24, 26, 28. http://www.aapg.org/explorer/2008/09sep/co2.cfm

Brown, W.T., 2001, Natural gas potential of the Almond Formation coals, Greater Green River Basin, southwestern Wyoming, in M.R. Silverman, ed., Emerging coalbed methane plays of North America: Denver, CO, Petroleum Frontiers, v. 18, no. 3, p. 29-39.Brown, W.T., Jr., 2003, Natural gas potential of the Almond Formation coals, Greater Green River Basin, southwestern Wyoming, in Emerging coalbed methane plays of North America, part 1: Petroleum Frontiers, v. 18, no. 3, p. 29-39.Brownfield, M.E., 2002, Characterization and modes of occurrence of elements in feed coal and fly ash—an integrated approach: U.S. Geological Survey, Fact Sheet 038-02, 4 p. (http://greenwood.cr.usgs.gov/pub/fact-sheets/fs-0038-02/)Brownfield, M.E., J.G. Self, and T.J. Mercier, 2011, Fischer Assay histograms of oil-shale drill cores and rotary cuttings from the Great Divide, Green River, and Washakie Basins, southwestern Wyoming: U.S. Geological Survey, Digital Data Series DDS-69-DD, chapter 6, 9 p. http://pubs.usgs.gov/dds/dds-069/dds-069-dd/REPORTS/69_DD_CH_6.pdfBrownfield, M.E., Johnson, R.C., Self, J.G., and Mercier, T.J., 2009, Nahcolite resources in the Green River Formation, Piceance Basin, northwestern Colorado: U.S. Geological Survey Fact Sheet 2009–3011, 4 p. http://pubs.usgs.gov/fs/2009/3011/

Bruner, K.R., A.V. Oldham, T.E. Repine, Jr., A.K. Markowski, and J.A. Harper, 1995, Geological aspects of coalbed methane in the northern Appalachian coal basin, southwestern Pennsylvania and north-central West Virginia: Pennsylvanian Geological Survey, 4 th ser., Open-File Report 98-13, 72 p.

Brunner, D., 2000, Enhanced gob gas recovery: U.S. Environmental Protection Agency, 18 p. (www.epa.gov/coalbed, see CMOP Library, CMOP Reports)Brunner, D., 2000, Enhanced gob gas recovery: U.S. Environmental Protection Agency, 18 p. (www.epa.gov/coalbed, see CMOP Library, CMOP Reports)

Buchanan, R., and T.R. Carr, 2011, Geologic sequestration of carbon dioxide in Kansas: Kansas Geological Survey, Public Information Circular 27, 4 p. http://www.kgs.ku.edu/Publications/PIC/pic27.html

Buiskool Toxopeus, J.M.A., 1983, Selection criteria for the use of vitrinite reflectance as a maturity tool, in J. Brooks, ed., Petroleum geochemistry and exploration of Europe: Oxford, Blackwell Scientific Publications, p. 295-307.

Bullock, J.H., Jr., J.D. Cathcart, and W.J. Betterton, 2002, Analytical methods utilized by the United States Geological Survey for the analysis of coal and coal combustion by-products: U.S. Geological Survey Open-File Report 02-389, 14 p.Bullock, J.H., Jr., J.D. Cathcart, and W.J. Betterton, 2002, Analytical methods utilized by the United States Geological Survey for the analysis of coal and coal combustion by-products: U.S. Geological Survey Open-File Report 02-389, 14 p.

Bunt, J.R., and F.B. Waanders, 2008, An understanding of lump coal physical property behaviour (density and particle size effects) impacting on a commercial-scale Sasol-Lurgi FBDB gasifier: Fuel, v. 87, p. 2856-2865.Bunt, J.R., J.P. Joubert, and F.B. Waanders, 2008, Coal char temperature profile estimation using optical reflectance for a commercial-scale Sasol-Lurgi FBDB gasifier: Fuel, v. 87, p. 2849-2855.Bunt, J.R., J.P. Joubert, and F.B. Waanders, 2008, Coal char temperature profile estimation using optical reflectance for a commercial-scale Sasol-Lurgi FBDB gasifier: Fuel, v. 87, p. 2849-2855.Bunt, J.R., N.J. Wagner, and F.B. Waanders, 2009, Carbon particle type characterization of the carbon behavior impacting on a commercial-scale Sasol-Lurgi FBDB gasifier: Fuel, v. 88, p. 771-779.Buo, T.V., R.J. Gray, and R.M. Patalsky, 2000, Reactivity and petrography of cokes for ferrosilicon and silicon production: International Journal of Coal Geology, v. 43, p. 243-256.Buranek, A.M., and A.L. Crawford, 1952, Notes on resinous coals of Utah: Utah Geological and Mineralogical Survey Monograph Series 2, p. 3-9.Burden, E.T., S.H. Williams, and P.K. Mukhopadhyay, 1993, Comparative analysis of thermal maturation indices for acritarchs, spores, graptolites and vitrinite from Paleozoic strata, western Newfoundland: GAC/MAC Annual Meeting, Waterloo 93, Programs with Abstracts, p. A-14.

Burgess, C.E., and H.H. Schobert, 1998, Relationship of coal characteristics determined by pyrolysis/gas chromatography/mass spectrometry and nuclear magnetic resonance to liquefaction reactivity and product composition: Energy & Fuels, v. 12, p. 1212-1222.

Burkhard, M., and W. Kalkreuth, 1989, Coalification in the northern Wildhorn nappe and adjacent units, western Switzerland. Implications for tectonic burial histories: International Journal of Coal Geology, v. 11, p. 47-64.Burkhard, M., and W. Kalkreuth, 1989, Coalification in the northern Wildhorn nappe and adjacent units, western Switzerland. Implications for tectonic burial histories: International Journal of Coal Geology, v. 11, p. 47-64.

Burne, R.V., and A.J. Kantsler, 1977, Geothermal constraints on the hydrocarbon potential of the Canning Basin, western Australia: BMR Journal of Australian Geology and Geophysics, v. 2, p. 271-288.

Burnham, A.K., and J.J. Sweeney, 1989, A chemical kinetic model of vitrinite maturation and reflectance: Geochimica et Cosmochimica Acta, v. 53, p. 2649-2657.Burrell, G.A., and F.M. Seibert, 1913, The sampling and examination of mine gases and natural gas: U.S. Bureau of Mines Bulletin 42, 116 p.Burrell, G.A., I.W. Robertson, and G.G. Oberfell, 1916, Black damp in mines: U.S. Bureau of Mines Bulletin 105, 88 p.

Burton, E., J. Friedmann, and R. Upadhye, 2007, Best practices in underground coal gasification: Lawrence Livermore National Laboratory, Technical Report W-7405-Eng-48, 119 p.Busch, A., and Y. Gensterblum, 2011, CBM and CO2-ECBM related sorption processes in coal: a review: International Journal of Coal Geology, v. 87, p. 49-71.Busch, A., and Y. Gensterblum, 2011, CBM and CO2-ECBM related sorption processes in coal: a review: International Journal of Coal Geology, v. 87, p. 49-71.Busch, A., B.M. Krooss, Y. Gensterblum, F. van Bergen, and H.J.M. Pagnier, 2003, High-pressure adsorption of methane, carbon dioxide and their mixtures on coals with a special focus on the preferential sorption behaviour: Journal of Geochemical Exploration, v. 78-79, p. 671-674.Busch, A., S. Alles, Y. Gensterblum, D. Prinz, D.N. Dewhurst, M.D. Raven, H. Stanjek, and B.M. Krooss, 2008, Carbon dioxide storage potential of shales: International Journal of Greenhouse Gas Control, v. 2, p. 297-308.Busch, A., S. Alles, Y. Gensterblum, D. Prinz, D.N. Dewhurst, M.D. Raven, H. Stanjek, and B.M. Krooss, 2008, Carbon dioxide storage potential of shales: International Journal of Greenhouse Gas Control, v. 2, p. 297-308.Busch, A., Y. Gensterblum, and B.M. Krooss, 2003, Methane and CO2 sorption and desorption measurements on dry Argonne premium coals: pure components and mixtures: International Journal of Coal Geology, v. 55, p. 205-224.Busch, A., Y. Gensterblum, and B.M. Krooss, 2003, Methane and CO2 sorption and desorption measurements on dry Argonne premium coals: pure components and mixtures: International Journal of Coal Geology, v. 55, p. 205-224.Busch, A., Y. Gensterblum, B.M. Krooss, and N. Siemons, 2006, Investigation of high-pressure selective adsorption/desorption behaviour of CO2 and CH4 on coals: an experimental study: International Journal of Coal Geology, v. 66, p. 53-68.Busch, A., Y. Gensterblum, B.M. Krooss, and N. Siemons, 2006, Investigation of high-pressure selective adsorption/desorption behaviour of CO2 and CH4 on coals: an experimental study: International Journal of Coal Geology, v. 66, p. 53-68.Busch, A., Y. Gensterblum, B.M. Krooss, and R. Littke, 2004, Methane and carbon dioxide adsorption—diffusion experiments on coal: upscaling and modeling: International Journal of Coal Geology, v. 60, p. 151-168.Busch, A., Y. Gensterblum, B.M. Krooss, and R. Littke, 2004, Methane and carbon dioxide adsorption—diffusion experiments on coal: upscaling and modeling: International Journal of Coal Geology, v. 60, p. 151-168.

Bustin, A.M.M., and R.M. Bustin, 2008, Coal reservoir saturation: Impact of temperature and pressure: AAPG Bulletin, v. 92, p. 77-86.Bustin, A.M.M., and R.M. Bustin, 2012, Horseshoe Canyon and Belly River coal measures, south central Alberta: Part 2—Modeling reservoir properties and producible gas: Bulletin of Canadian Petroleum Geology, v. 59, p. 235-260.

Bujnowska, B., and M. Zielinska-Blajet, 1995, The relation between physicochemical properties of high volatile bituminous coals and structure of semicokes and cokes, in J.A. Pajares and J.M.D. Tascon, eds., Coal science: New York, Elsevier, Coal Science and Technology 24, v. 1, p. 1053-1056.

Bunger, J.W., P.M. Crawford, and H.R. Johnson, 2004, Hubbert revisited—5. Is oil shale America’s answer to peak-oil challenge?: Oil & Gas Journal, v. 102.30, p. 16-18, 20, 22-24. (http://www.fe.doe.gov/programs/reserves/publications/Pubs-NPR/40010-373.pdf)

Burger, K., and H.H. Damberger, 1985, Tonsteins in the coalfields of western Europe and North America, in Compte Rendu of IXICC: SIU Press, Carbondale, v. 4, p. 433-448.

Burgess, J.D., 1974, Microscopic examination of kerogen (dispersed organic matter) in petroleum exploration, in R.R. Dutcher, P.A. Hacquebard, J.M. Schopf, and J.A. Simon, eds., Carbonaceous materials as indicators of metamorphism: GSA Special Paper 153, p. 19-30.Burke, L., 2011, Carbon dioxide fluid-flow modeling and injectivity calculations: U.S. Geological Survey, Scientific Investigations Report 2011-5083, 24 p. http://pubs.usgs.gov/sir/2011/5083/sir2011-5083.pdf

Burkley, L.A., and J.R. Castano, 1985, Alaska North Slope oil-source rock correlation study, in L.B. Magoon and G.E. Claypool, eds., Alaska North Slope oil/rock correlation study: AAPG Studies in Geology 20, p. 95-121.

Burnham, A.K., 1995, Chemical kinetics and oil shale process design, in C. Snape, ed., Proceedings of the NATO Advanced Study Institute on Composition, Geochemistry, and Conversion of Oil Shales: Akcay, Turkey, July 1993, Dordrecht, Kluwer Academic Publishers, p. 263-276.

Burruss, R.C., 1991, Practical aspects of fluorescence microscopy of petroleum fluid inclusions, in C.E. Barker and O.C. Kopp, eds., Luminescence microscopy and spectroscopy: qualitative and quantitative applications: SEPM Short Course 25, p. 1-7.Burruss, R.C., and S.T. Brennan, 2003, Geologic sequestration of carbon dioxide; an energy resource perspective: U.S.G.S. Fact Sheet FS 0026-03, 2 p. http://pubs.usgs.gov/fs/fs026-03/

Busch, A., Y. Gensterblum, N. Siemons, B. M. Kroos, F. van Bergen, H. J. M. Pagnier, and P. David, 2003, Investigation of preferential sorption behaviour of CO 2 and CH4 on coals by high pressure adsorption/desorption experiments with gas mixtures: Tuscaloosa, Alabama, University of Alabama, College of Continuing Studies, 2003 International Coalbed Methane Symposium Proceedings, paper 0350, 14 p.Busch, R.M., R.R. West, F.J. Barrett, and T.R. Barrett, 1985, Cyclothems versus a hierarchy of transgressive-regressive units, in W.L. Watney, R.L. Kaesler, and K.D. Newell, conveners, Recent interpretations of late Paleozoic cyclothems: Midcontinent SEPM Proceedings of Third Annual Meeting and Field Conference, p. 141-153.

Bustin, R.M. M. Mastalerz, and M. Raudsepp, 1996, Electron-probe microanalysis of light elements in coal and other kerogen: International Journal of Coal Geology, v. 32, p. 5-30.Bustin, R.M., 1980, Oxidation characteristics of some sheared coal seams of the Mist Mountain Formation, southeastern Canadian Cordillera: Geological Survey of Canada, Paper 80-1B, p. 249-254.Bustin, R.M., 1988, Sedimentology and characteristics of dispersed organic matter in Tertiary Niger Delta: origin of source rocks in a deltaic environment: AAPG Bulletin, v. 72, p. 277-298.Bustin, R.M., 1988, Sedimentology and characteristics of dispersed organic matter in Tertiary Niger Delta: origin of source rocks in a deltaic environment: AAPG Bulletin, v. 72, p. 277-298.Bustin, R.M., 1991, Quantifying macerals: some statistical and practical considerations: International Journal of Coal Geology, v. 17, p. 213-238.Bustin, R.M., 1997, Importance of fabric and composition on the stress sensitivity of permeability in some coals, northern Sydney basin, Australia: relevance to coalbed methane exploitation: AAPG Bulletin, v. 81, p. 1894-1908.Bustin, R.M., 2000, Hydrogen sulphide sorption on coal with comparisons to methane, carbon dioxide, nitrogen and hydrogen sorption: implications for acid gas sequestering and co-production of methane (abstract): TSOP Abstracts and Program, v. 17, p. 15.Bustin, R.M., 2001, Hydrogen sulphide sorption on coal with comparisons to methane, carbon dioxide, nitrogen and hydrogen: implications for acid gas sequestration and co-production of methane: Tuscaloosa, Alabama, Proceedings, International Coalbed Methane Symposium, Paper 112, p. 343-350.Bustin, R.M., 2001, Hydrogen sulphide sorption on coal with comparisons to methane, carbon dioxide, nitrogen and hydrogen: implications for acid gas sequestration and co-production of methane: Tuscaloosa, Alabama, Proceedings, International Coalbed Methane Symposium, Paper 112, p. 343-350.

Bustin, R.M., A.R. Cameron, D.A. Grieve, and W.D. Kalkreuth, 1985, Coal petrology -- its principles, methods and applications, second revised edition: Geological Association of Canada Short Course Notes 3, 230 p. (see p. 89-95)Bustin, R.M., A.R. Cameron, D.A. Grieve, and W.D. Kalkreuth, 1985, Coal petrology, its principles, methods, and applications: Geological Association of Canada, Short Course Notes, v. 3, Second revised edition, 230 p.Bustin, R.M., A.R. Cameron, D.A. Grieve, and W.D. Kalkreuth, 1985, Coal petrology—its principles, methods and applications (second revised edition): Geological Association of Canada, Short Course Notes v. 3, 230 p.Bustin, R.M., and A.M.M. Bustin, 2012, Horseshoe Canyon and Belly River coal measures, south central Alberta: Part 1—Total original gas-in-place: Bulletin of Canadian Petroleum Geology, v. 59, p. 207-234.

Bustin, R.M., and Y. Guo, 1999, Abrupt changes (jumps) in reflectance values and chemical compositions of artificial charcoals and inertinite in coals: International Journal of Coal Geology, v. 38, p. 237-260.Bustin, R.M., C. Link, and F. Goodarzi, 1989, Optical properties and chemistry of graptolite periderm following laboratory simulated maturation: Organic Geochemistry, v. 14, p. 355-364.Bustin, R.M., J.V. Ross, and I. Moffat, 1986, Vitrinite anisotropy under differential stress and high confining pressure and temperature: preliminary observations: International Journal of Coal Geology, v. 6, p. 343-351.

Bustin, R.M., M. Mastalerz, and K.R. Wilks, 1993, Direct determination of carbon, oxygen, and nitrogen content in coal using the electron microprobe: Fuel, v. 72, p. 181-185.Bustin, R.M., M. Mastalerz, and K.R. Wilks, 1993, Direct determination of carbon, oxygen, and nitrogen in coal using the electron microprobe: Fuel, v. 72, p. 181-185.Bustin, R.M., M. Mastalerz, K.R. Wilks, and M. Lamberson, 1993, Direct major (C,N,O) and minor element analysis of coal macerals by electron microprobe: Energy Sources, v. 15, p. 653-669.Bustin, R.M., X. Cui, and L. Chikatamarla, 2008, Impacts of volumetric strain on CO2 sequestration in coals and enhanced CH4 recovery: AAPG Bulletin, v. 92, p. 15-29.Bustin, R.M., X. Cui, and L. Chikatamarla, 2008, Impacts of volumetric strain on CO2 sequestration in coals and enhanced CH4 recovery: AAPG Bulletin, v. 92, p. 15-29.Butala, S.J.M., J.C. Medina, T.Q. Taylor, C.H. Bartholomew, and M.L. Lee, 2000, Mechanisms and kinetics of reactions leading to natural gas formation during coal maturation: Energy Fuels, v. 14, p. 235-259.Butland, C.I., and T.A. Moore, 2008, Secondary biogenic coal seam gas reservoirs in New Zealand: A preliminary assessment of gas contents: International Journal of Coal Geology, v. 76, p. 151-165.Butler, J., H. Marsh, and F. Goodarzi, 1988, World coals: genesis of the world’s major coalfields in relation to plate tectonics: Fuel, v. 67, p. 269-274.Bybee, K., 2002, Multiseam coal stimulation by coiled-tubing fracturing: Journal of Petroleum Technology, v. 54, p. 47.Bybee, K., 2006, A parametric study of horizontal and multilateral wells in coalbed-methane reservoirs: Journal of Petroleum Technology, v. 58, no. 5, p. 71-72.Bybee, K., 2009, Maximizing energy at coalface for coalbed-methane fracturing: Journal of Petroleum Technology, v. 61, no. 6, p. 59-60.

Byrer, C.W., T.H. Mroz, and G.L. Covatch, 1987, Coalbed methane production potential in U.S. basins: Journal of Petroleum Technology, v. 39, no. 7, p. 821-834.Cady, G.H., 1936, The occurrence of coal balls in No. 6 coal bed at Nashville, Illinois: Transactions of the Illinois Academy of Science, v. 29, p. 157-158.Cady, G.H., 1939, Nomenclature of the megascopic description of Illinois coals: Economic Geology, v. 34, p. 475-494. (ISGS Circular 46)Cady, G.H., 1942, Modern concepts of the physical constitution of coal: Journal of Geology, v. 50, p. 337-356. (proposed the term phyteral)Cady, G.H., 1949, Coal geology: an opportunity for research and study: Economic Geology, v. 44, p. 1-12.Cagigas, A., J.B. Escudero, M.J.D. Low, J.J. Pis, and J.M.D. Tascon, 1987, A comparison of various characterization techniques for low-temperature oxidation of coal: Fuel Processing Technology, v. 15, p. 245-256.Cai, Y., D. Liu, J.P. Mathews, Z. Pan, D. Elsworth, Y. Yao, J. Li, and X. Guo, 2014, Permeability evolution in fractured coal — Combining triaxial confinement with X-ray computed tomography, acoustic emission and ultrasonic techniques: International Journal of Coal Geology, v. 122, p. 91-104.Cai, Y., D. Liu, Y. Yao, J. Li, and Y. Qiu, 2011, Geological controls on prediction of coalbed methane of No. 3 coal seam in southern Qinshui Basin, north China: International Journal of Coal Geology, v. 88, p. 101-112.Cai, Y., D. Liu, Y. Yao, Z. Li, and Z. Pan, 2014, Partial coal pyrolysis and its implication to enhance coalbed methane recovery, part I: An experimental investigation: Fuel, v. 132, p. 12-19.

Bustin, R.M., A.E. Cameron, D.A. Grieve, and W.D. Kalkreuth, 1985, Coal petrology, its principles, methods and applications, 2 nd edition: Geological Association of Canada, Short Course Notes, No. 3, 230 p.

Bustin, R.M., and C.R. Clarkson, 1998, Geological controls on coalbed methane reservoir capacity and gas content, in P.C. Lyons, ed., Special issue: Appalachian coalbed methane: International Journal of Coal Geology, v. 38, p. 3-26.

Bustin, R.M., M. Mastalerz, and K. Wilks, 1992, Electron microprobe determination of carbon, oxygen, and nitrogen content of in-situ macerals, in G. Vourvopoulos, ed., Elemental analysis of coal and its by-products: New Jersey, World Scientific, p. 228-231.Bustin, R.M., M. Mastalerz, and K.R. Wilks, 1992, Electron microprobe determination of carbon, oxygen and nitrogen content in in-situ macerals, in George Vorvopoulos, ed., Elemental Analysis of Coal and its By-products: Int. Conf Proc., Kentucky, World Scientific Publishing Co. Pte. Ltd. Singapore, p. 228-231.

Byrer, C.W., and H.G. Guthrie, 1999, Coal deposits: potential geological sink for sequestering carbon dioxide emissions from power plants, in B. Eliasson, P.W.F. Riemer, and A. Wokaun, eds., Greenhouse gas control technologies: Pergamon, Elsevier Science Ltd., p. 181-187.

Calder, J.H., 1994, The impact of climate change, tectonism and hydrology on the formation of Carboniferous tropical intermontane mires: the Springhill coalfield, Cumberland Basin, Nova Scotia: Palaeogeography, Palaeoclimatology, Palaeoecology, v. 106, p. 323-351.Calder, J.H., and M.R. Gibling, 1994, The Euramerican coal province: controls on late Paleozoic peat accumulation: Palaeogeography, Palaeoclimatology, Palaeoecology, v. 106, p. 1-21.

Calemma, V., G. del Piero, R. Rausa, and E. Girardi, 1995, Changes in optical properties of coal during air oxidation at moderate temperature: Fuel, v. 74, p. 383-388.Calemma, V., R. Rausa, R. Margarit, and E. Girardi, 1988, FTIR study of coal oxidation at low temperature: Fuel, v. 67, p. 764-770.Calkins, W.H., 1994, The chemical forms of sulfur in coal, a review: Fuel, v. 73, p. 475-.Callejon, A.F., and K.K. Bissada, 2002, Role of coals and carbonaceous shales in the generation of oil in the eastern Venezuela basin: a "petroleum system approach" (abstract): TSOP Abstracts and Program, v. 18, p. 20.

Cameron, A.R., 1978, Megascopic description of coal with particular reference to seams in southern Illinois: ASTM Special Technical Publication (STP) 661, p. 9-32.

Cameron, A.R., 1991, Regional patterns of reflectance in lignites of the Ravenscrag Formation, Saskatchewan, Canada: Organic Geochemistry, v. 17, p. 223-242.Cameron, A.R., and G. Leclair, 1975, Extraction of uranium from aqueous solutions by coals of different rank and petrographic composition: Geological Survey of Canada Paper 74-35, 11 p.Cameron, A.R., and W.D. Kalkreuth, 1982, Petrological characteristics of Jurassic-Cretaceous coals in the foothills and Rocky Mountains of western Canada: Utah Geological and Mineral Survey Bulletin 118, p. 163-167.Cameron, A.R., F. Goodarzi, and J. Potter, 1994, Coal and oil shale of early Carboniferous age in northern Canada: significance for paleoenvironmental and paleoclimatic interpretations: Palaeogeography, Palaeoclimatology, Palaeoecology, v. 106, p. 135-155.Cameron, A.R., W.D. Kalkreuth, and C. Koukouzas, 1984, The petrology of Greek brown coals: International Journal of Coal Geology, v. 4, p. 173-207.Cameron, J.R., I.D. Palmer, and Z.A. Moschovidis, 2007, Effectiveness of horizontal wells in CBM: 2007 International Coalbed Methane Symposium, Tuscaloosa, AL, Paper 0716, 18 p.Campbell, B., 2002, Courts wrestle with CBM ownership: American Oil & Gas Reporter, v. 45, no. 9, p. 34-36.Campbell, B., 2003, Coalbed methane potential excites Illinois Basin: American Oil & Gas Reporter, v. 46, no. 6, p. 119-120.Campbell, C., 2008, State of the basin: A brief summary of the current legal and academic interest in the Powder River Basin, Wyoming: RMAG Outcrop, v. 57, no. 9, p. 6, 17, 27-29.Campbell, J.D., and M.P. du Plessis, 1983, Alberta Plains coal regions: potential feedstock for coal conversion by liquefaction and pyrolysis: Alberta Research Council, Information Series 101, 21 p.Campbell, M.R., 1929, The coal fields of the United States: U.S. Geological Survey Professional Paper 100.

Cao, X., J.E. Birdwell, M.A. Chappell, Y. Li, J. Pignatello, and J. Mao, 2013, Characterization of oil shale, isolated kerogen, and postpyrolysis residues using advanced 13C solid-state nuclear magnetic resonance spectroscopy: AAPG Bulletin, v. 97, p. 421-436.

Cao, Y., A. Davis, R. Liu, X. Liu, and Y. Zhang, 2003, The influence of tectonic deformation on some geochemical properties of coals—a possible indicator of outburst potential: International Journal of Coal Geology, v. 53, p. 69-79.Cao, Y., D. He, and D.C. Glick, 2001, Coal and gas outbursts in footwalls of reverse faults: International Journal of Coal Geology, v. 48, p. 47-63.Cao, Y., D. He, and D.C. Glick, 2001, Coal and gas outbursts in footwalls of reverse faults: International Journal of Coal Geology, v. 48, p. 47-63.Cao, Y., G.D. Mitchell, A. Davis, and D. Wang, 2000, Deformation metamorphism of bituminous and anthracite coals from China: International Journal of Coal Geology, v. 43, p. 227-242.Cao, Y., Y. Duan, S. Kellie, L. Li, W. Xu, J.T. Riley, W.-P. Pan, P. Chu, A.K. Mehta, and R. Carty, 2005, Impact of coal chlorine on mercury speciation and emission from a 100-MW utility boiler with cold-side electrostatic precipitators and low-NOx burners: Energy Fuels, v. 19, p. 842-854.Caramanna, G., Y. Wei, M. M. Maroto-Valer, P. Nathanail, and M. Steven, 2013, Laboratory experiments and field study for the detection and monitoring of potential seepage from CO2 storage sites: Applied Geochemistry, v. 30, p. 105-113.Cardott, B.J., 1991, Organic petrology of epi-impsonite at Page, Oklahoma, U.S.A.: Organic Geochemistry, v. 17, p. 185-191.

Calder, J.H., 1993, The evolution of a ground-water-influenced (Westphalian B) peat-forming ecosystem in a piedmont setting: the no. 3 seam, Springhill coalfield, Cumberland Basin, Nova Scotia, in J.C. Cobb and C.B. Cecil, eds., Modern and ancient coal-forming environments: Geological Society of America Special Paper 286, p. 153-180.

Calder, J.H., M.R. Gibling, and R.K. Mukhopadhyay, 1991, Peat formation in a Westphalian B piedmont setting, Cumberland Basin, Nova Scotia: implications for the maceral-based interpretation of rheotrophic and raised paleomires, in P. Bertrand, ed., Coal: formation, occurrence and related properties: Bulletin de la Societe Geologique de France, v. 162, p. 283-298.

Cameron, A.R., 1974, Principles of coal petrography, in J.F. Fryer, J.D. Campbell, and J.G. Speight, eds., Symposium on coal evaluation: Alberta Research Council Information Series 76, p. 51-69.Cameron, A.R., 1978, Megascopic description of coal with particular reference to seams in southern Illinois, in R.R. Dutcher, ed., Field description of coal: Philadelphia, PA, American Society for Testing and Materials, Special Technical Publication 661, p. 9-32.

Cameron, A.R., 1984, Comparison of reflectance data for various macerals from coals of the Kootenay Group, southeastern British Columbia, in R.L. Houghton and E.N. Clausen, eds., 1984 Symposium on the Geology of Rocky Mountain Coal: North Dakota Geological Society, Publication 84-1, p. 61-75.

Campen, E.B., and E.B. Campen, 2002, Basic log analysis in coalbed methane exploration, in S.D. Schwochow and V.F. Nuccio, eds., Coalbed methane of North America, II: Rocky Mountain Association of Geologists, p. 17-23.Campen, E.B., and J.R. Gruber, Jr., 1991, Coal and coalbed methane resources of Montana, in S.D. Schwochow, D.K. Murray, and M.F. Fahy, eds., Coalbed methane of western North America: Denver, CO, Rocky Mountain Association of Geologists Guidebook, p. 265-272.Cane, R.F., 1976, The origin and formation of oil shale, in T.F. Yen and G.V. Chilingarian, eds., Oil shale: Elsevier, p. 27-60.Cao, D., X. Fan, H. Guan, C. Wu, X. Shi, and Y. Jia, 2007, Geological models of spontaneous combustion in the Wuda coalfield, Inner Mongolia, China, in G.B. Stracher, ed., Geology of coal fires: case studies from around the world: GSA Reviews in Engineering Geology 18, p. 23-30.

Cao, X., M. Mastalerz, M.A. Chappell, L.F. Miller, Y. Li, and J. Mao, 2011, Chemical structures of coal lithotypes before and after CO2 adsorption as investigated by advanced solid-state 13C nuclear magnetic resonance spectroscopy: International Journal of Coal Geology, v. 88, p. 67-74.

Cardott, B.J., 1999, Coalbed methane activity in Oklahoma, in B.J. Cardott, compiler, Oklahoma coalbed-methane workshop: OGS Open-File Report OF 6-99, p. 47-66.Cardott, B.J., 2000, Coalbed methane activity in Oklahoma, in B.J. Cardott, compiler, Oklahoma coalbed-methane workshop: OGS Open-File Report OF 2-2000, p. 13-35.Cardott, B.J., 2001, Coalbed-methane activity in Oklahoma, 2001, in B.J. Cardott, compiler, Oklahoma coalbed-methane workshop 2001: OGS Open-File Report 2-2001, p. 93-118.Cardott, B.J., 2001, Introduction to coal as gas source rock and reservoir, in B.J. Cardott, compiler, Oklahoma coalbed-methane workshop 2001: OGS Open-File Report 2-2001, p. 1-27.Cardott, B.J., 2001, Oklahoma coalbed-methane completions, 1988 to 1996, in K.S. Johnson, ed., Pennsylvanian and Permian geology and petroleum in the southern Midcontinent, 1998 symposium: OGS Circular 104, p. 81-85.

Cardott, B.J., 2002, Lessons learned from coalbed-methane exploration (abstract): TSOP Abstracts and Program, v. 18, p. 21-22.

Cardott, B.J., 2013, Hartshorne coal rank applied to Arkoma Basin coalbed methane activity, Oklahoma, USA: International Journal of Coal Geology, v. 108, p. 35-46.Cardott, B.J., and D.F. Bensley, 1989, Toward a standardization of random vitrinite reflectance (abstract): TSOP Abstracts and Program, v. 6, p. 36-38.Cardott, B.J., and D.F. Bensley, 1989, Toward a standardization of random vitrinite reflectance: The Society for Organic Petrology, Abstracts and Program, v. 6, p. 36-38.Cardott, B.J., and M.A. Biddick, 2003, Coalbed methane: economic success in the Arkoma Basin, Oklahoma (abstract): AAPG Mid-Continent Section Meeting, Official Program Book, p. 26.

Cardott, B.J., N.H. Suneson, and C.A. Ferguson, 1989, The Page impsonite mine, Le Flore County, Oklahoma: Oklahoma Geological Survey, Oklahoma Geology Notes, v. 49, p. 32-39.

Carlton, D.R., 2006, Discovery and development of a giant coalbed methane resource, Raton Basin, Las Animas County, southeast Colorado: The Mountain Geologist, v. 43, no. 3, p. 231-236.Carpenter, A. and N. Skorupska, 1993, Coal combustion — analysis and testing: IEA Coal Research, IEACR/64, 97 p.Carpenter, A.M., 1988, Coal classification: IEA Coal Research, IEACR/12, 104 p. (chapter 7 is on combustion)Carpenter, A.M., 1988, Coal classification: London, IEA Coal Research, IEACR/12, 104 p.Carpenter, A.M., 1988, Coal classification: London, IEA Coal Research, IEACR/12, 104 p.Carpenter, A.M., 1988, Coal classification: London, IEA Coal Research, IEACR/12, 104 p. (liquefaction, p. 64-77)Carpenter, A.M., 1995, Coal blending for power stations: IEA Coal Research, IEACR/81, 83 p.Carr, A.D., 1999, A vitrinite reflectance kinetic model incorporating overpressure retardation: Marine and Petroleum Geology, v. 16, p. 355-377.Carr, A.D., 1999, A vitrinite reflectance kinetic model incorporating overpressure retardation: Marine and Petroleum Geology, v. 16, p. 355-377.Carr, A.D., 1999, A vitrinite reflectance kinetic model incorporating overpressure retardation: Marine and Petroleum Geology, v. 16, p. 355-377.Carr, A.D., 2000, Suppression and retardation of vitrinite reflectance, part 1. Formation and significance for hydrocarbon generation: Journal of Petroleum Geology, v. 23, p. 313-343.Carr, A.D., 2000, Suppression and retardation of vitrinite reflectance, part 1. Formation and significance for hydrocarbon generation: Journal of Petroleum Geology, v. 23, p. 313-343.Carr, A.D., 2000, Suppression and retardation of vitrinite reflectance, part 2. Derivation and testing of a kinetic model for suppression: Journal of Petroleum Geology, v. 23, p. 475-496.Carr, A.D., 2000, Suppression and retardation of vitrinite reflectance, part 2. Derivation and testing of a kinetic model for suppression: Journal of Petroleum Geology, v. 23, p. 475-496.Carr, A.D., 2003, Thermal history model for the south central graben, North Sea, derived using both tectonics and maturation: International Journal of Coal Geology, v. 54, p. 3-19.Carr, A.D., and J.E. Williamson, 1990, The relationship between aromaticity, vitrinite reflectance and maceral composition of coals: implications for the use of vitrinite reflectance as a maturation parameter: Organic Geochemistry, v. 16, p. 313-323.Carr, A.D., and J.E. Williamson, 1990, The relationship between aromaticity, vitrinite reflectance, and maceral composition of coals: implications for the use of vitrinite reflectance as a maturation parameter: Organic Geochemistry, v. 16, p. 313-323.Carr, T.R., and D.F. Merriam, 2005, CO2 sequestration, petroleum accumulation, and groundwater flow in Kansas: a regional assessment (abstract): 2005 AAPG Annual Conventional Abstracts Volume, v. 14, p. A23.Carr, T.R., D.F. Merriam, and J.D. Bartley, 2005, Use of relational databases to evaluate regional petroleum accumulation, groundwater flow, and CO2 sequestration in Kansas: AAPG Bulletin, v. 89, p. 1607-1627.

Carras, J.N., S.J. Day, A. Saghafi, and D.J. Williams, 2009, Greenhouse gas emissions from low-temperature oxidation and spontaneous combustion at open-cut coal mines in Australia: International Journal of Coal Geology, v. 78, p. 161-168.Carrascal-Miranda, E.R., and I. Suárez-Ruiz, 2004, Short description of the Peruvian coal basins: International Journal of Coal Geology, v. 58, p. 107-117.Carrie, J., H. Sanei, and G. Stern, 2012, Standardisation of Rock-Eval pyrolysis for the analysis of recent sediments and soils: Organic Geochemistry, v. 46, p. 38-53.

Carroll, R.E., and J.C. Pashin, 2002, Carbon sequestration potential of coalbed methane reservoirs in the Black Warrior basin: relationship of sorption capacity to coal quality (abstract): TSOP Abstracts and Program, v. 18, p. 23-24.Carroll, R.E., and J.C. Pashin, 2002, Carbon sequestration potential of coalbed methane reservoirs in the Black Warrior basin: relationship of sorption capacity to coal quality (abstract): TSOP Abstracts and Program, v. 18, p. 23-24.

Cardott, B.J., 2002, Coalbed methane development in Oklahoma, in S.D. Schwochow and V.F. Nuccio, eds., Coalbed methane of North America, II: Rocky Mountain Association of Geologists, p. 83-98.Cardott, B.J., 2002, Coalbed-methane activity in Oklahoma, 2002 update, in B.J. Cardott, compiler, Fourth annual Oklahoma coalbed-methane workshop: OGS Open-File Report 9-2002, p. 56-82.

Cardott, B.J., 2005, Coalbed-methane activity in Oklahoma, 2004 update, in B.J. Cardott, ed., Unconventional energy resources in the southern Midcontinent, 2004 symposium: Oklahoma Geological Survey Circular 110, p. 69-81.Cardott, B.J., 2005, Overview of unconventional energy resources of Oklahoma, in B.J. Cardott, ed., Unconventional energy resources in the southern Midcontinent, 2004 symposium: Oklahoma Geological Survey Circular 110, p. 7-18.Cardott, B.J., 2012, Introduction to vitrinite reflectance as a thermal maturity indicator: AAPG Search and Discovery article No. 40928. http://www.searchanddiscovery.com/documents/2012/40928cardott/ndx_cardott.pdf

Cardott, B.J., and M.A. Kidwai, 1991, Graptolite reflectance as a potential thermal-maturation indicator, in K.S. Johnson, ed., Late Cambrian-Ordovician geology of the southern Midcontinent, 1989 symposium: Oklahoma Geological Survey Circular 92, p. 203-209.

Cardott, B.J., T.E. Ruble, and N.H. Suneson, 1993, Nature of migrabitumen and their relation to regional thermal maturity, Ouachita Mountains, Oklahoma, in F. Goodarzi and R.W. Macqueen, eds., Geochemistry and petrology of bitumen with respect to hydrocarbon generation and mineralization: Energy Sources, v. 15, p. 239-267.Cardott, B.J., T.E. Ruble, and N.H. Suneson, 1993, Nature of migrabitumen and their relation to regional thermal maturity, Ouachita Mountains, Oklahoma, in F. Goodarzi and R.W. Macqueen, eds., Geochemistry and petrology of bitumen with respect to hydrocarbon generation and mineralization: Energy Sources, v. 15, p. 239-267.

Carr, T.R., K.D. Newell, T.A. Johnson, W.M. Brown, and J.P. Lange, 2005, Coalbed-methane development in Kansas, in B.J. Cardott, ed., Unconventional energy resources in the southern Midcontinent, 2004 symposium: Oklahoma Geological Survey Circular 110, p. 63-65.

Carroll, A.R., 2009, Prospects and progress in the Green River Formation oil shale, western United States, in T. Carr, T. D’Agostino, W. Ambrose, J. Pashin, and N.C. Rosen, eds., Unconventional energy resources: making the unconventional conventional: 29 th Annual GCSSEPM Foundation Bob F. Perkins Research Conference, CD-ROM, p. 388-395.Carroll, R. E., and J. C. Pashin, 2003, Relationship of sorption capacity to coal quality: CO2 sequestration potential of coalbed methane reservoirs in the Black Warrior basin: Tuscaloosa, Alabama, University of Alabama College of Continuing Studies, 2003 International Coalbed Methane Symposium Proceedings, Paper 0317, 11 p.

Carroll, R.E., and J.C. Pashin, 2003, Relationship of sorption capacity to coal quality: CO2 sequestration potential of coal bed methane reservoirs in the Black Warrior Basin: Proceedings of the International Coal Bed Methane Symposium, paper 0317, 11 p.Carter, E.F., 1963, Coal: London, Frederik Muller Ltd., 143 p.

Carter, R.H., S.A. Holditch, J. Hinkel, and R. Jeffrey, 1989, Enhanced gas production through hydraulic fracturing of coal seams: Gas Research Institute, Final Report, GRI-90/0061, 71 p.Caruccio, F.T., J.C. Ferm, J. Horne, G. Geidel, and B. Baganz, 1977, Paleoenvironment of coal and its relation to drainage quality: EPA Program Report, EPA-600/7-77-067, 108 p.

Casagrande, D.J., and L.D. Erchull, 1976, Metals in Okefenokee peat-forming environments: relation to constituents found in coal: Geochimica et Cosmochimica Acta, v. 40, p. 387-393.Casagrande, D.J., K. Gronli, and N. Sutton, 1980, The distribution of sulfur and organic matter in various fractions of peat: Origins of sulfur in coal: Geochmica et Cosmochimia Acta, v. 44, p. 25-32.Casal, M.D., M.A. Díez, R. Alvarez, and C. Barriocanal, 2008, Primary tar of different coking coal ranks: International Journal of Coal Geology, v. 76, p. 237-242.Casareo, F.E., S.C. George, B.D. Batts, and P.J. Conaghan, 1996, The effects of varying tissue preservation on the aliphatic hydrocarbons within a high-volatile bituminous coal: Organic Geochemistry, v. 24, p. 785-800.Case, E.R., 1988, Living in interesting times: cokemaking today: Journal of Coal Quality, v. 7, no. 3, p. 77-78.Cashion, W.B., and J.R. Donnell, 1972, Chart showing correlation of selected key units in the organic-rich sequence of the Green River Formation, Piceance Creek Basin, Colorado, and Uinta Basin, Utah: U.S. Geological Survey, Oil and Gas Investigations Chart OC-65.

Castano, J.R., P.R. Johnson, and A.K. Killi, 1990, Thermal maturation of structureless organic matter: its petrographic expression (abstract): TSOP Abstracts and Program, v. 7, p. 26-27.

Cates, L. M., M. R. McIntyre, W. B. Hawkins, and R. H. Groshong, Jr., 2004, Structure and oil and gas production in the Black Warrior basin: Tuscaloosa, Alabama, University of Alabama College of Continuing Studies, 2004 International Coalbed Methane Symposium Proceedings, Paper 0440, 34 p.

Cecil, C.B., 1990, Paleoclimate controls on stratigraphic repetition of chemical and siliciclastic rocks: Geology, v. 18, p. 533-536.Cecil, C.B., 2013, An overview and interpretation of autocyclic and allocyclic processes and the accumulation of strata during the Pennsylvanian-Permian transition in the central Appalachian Basin, USA: International Journal of Coal Geology, v. 119, p. 21-31.

Cecil, C.B., R.W. Stanton, S.D. Allshouse, R.B. Finkelman, and L.P. Greenland, 1979, Geological controls on element concentrations in the Upper Freeport coal bed: Fuel, v. 24, p. 230-235.

Ceglarska- Stefańska, G., and K. Zarebska, 2005, Sorption of carbon dioxide–methane mixtures: International Journal of Coal Geology, v. 62, p. 211-222.Ceglarska-Stefańska, G., and K. Zarębska, 2002, The competitive sorption of CO2 and CH4 with regard to the release of methane from coal: Fuel Processing Technology, v. 77-78, p. 423-429.Ceglarska-Stefańska, G., and K. Zarębska, 2002, The competitive sorption of CO2 and CH4 with regard to the release of methane from coal: Fuel Processing Technology, v. 77-78, p. 423-429.Ceglarska-Stefańska, G., and K. Zarębska, 2005, Sorption of carbon dioxide-methane mixtures: International Journal of Coal Geology, v. 62, p. 211-222.Cerny, J., G. Sebor, J. Blazek, and D. Maxa, 1995, Coal structure and coal reactivity under liquefaction conditions: Erdöl und Kohle-Erdgas-Petrochemie, v. 48, nos. 4/5, p. 182-185.Cervik, J., 1969, Behaviour of coal-gas reservoirs: U.S. Bureau of Mines, Technical Progress Report 10, 10 p.

Chaffee, A.L., G. Lay, M. Marshall, W.R. Jackson, Y. Fei, T.V. Verheyen, P.J. Cassidy, and S.G. Scott, 2010, Structural characterization of Middle Jurassic, high-volatile bituminous Walloon Subgroup coals and correlation with the coal seam gas content: Fuel, v. 89, p. 3241-3249.Chaffee, A.L., G. Lay, M. Marshall, W.R. Jackson, Y. Fei, T.V. Verheyen, P.J. Cassidy, and S.G. Scott, 2010, Structural characterization of Middle Jurassic, high-volatile bituminous Walloon Subgroup coals and correlation with the coal seam gas content: Fuel, v. 89, p. 3241-3249.Chaffee, A.L., R.B. Johns, M.J. Baerken, J.W. De Leeuw, P.A. Schenck, and J.J. Boon, 1984, Chemical effects in gelification processes and lithotype formation in Victorian brown coal: Organic Geochemistry, v. 6, p. 409-416.Chagué-Goff, C., and W.S. Fyfe, 1996, Geochemical and petrographical characteristics of a domed bog, Nova Scotia: a modern analogue for temperate coal deposits: Organic Geochemistry, v. 24, p. 141-158.Chakrabartty, S.K., and M.P. du Plessis, 1982, Modern coal pyrolysis, a state-of-the-art review: Alberta Research Council Information Series 95, 46 p.

Carter, M.D., N.K. Gardner, R.E. Sergeant, E.V.M. Campbell, and N. Fedorko, III, 1990, Coal availability studies—a progress report (abstract), in L.M.H. Carter, ed., USGS research on energy resources—1990 program and abstracts: U.S. Geological Survey Circular 1060, p. 13-14.

Casagrande, D.J., 1987, Sulphur in peat and coal, in A.C. Scott, ed., Coal and coal-bearing strata: recent advances: Boston, Blackwell Scientific Publications, Geological Society Special Publication 32, p. 87-105.

Castaño, J.R., and D.M. Sparks, 1974, Interpretation of vitrinite reflectance measurements in sedimentary rocks and determination of burial history using vitrinite reflectance and authigenic minerals, in R.R. Dutcher, P.A. Hacquebard, J.M. Schopf, and J.A. Simon, eds., Carbonaceous materials as indicators of metamorphism: GSA Special Paper 153, p. 31-52.Castano, J.R., and D.M. Sparks, 1974, Interpretation of vitrinite reflectnce measurements in sedimentary rocks and determination of burial history using vitrinite reflectance and authigenic minerals, in R.R. Dutcher, P.A. Hacquebard, J.M. Schopf, and J.A. Simon, eds., Carbonaceous materials as indicators of metamorphism: Geological Society of America Special Paper 153, p. 31-52.

Catalina, J.C., D. Alarcon, and J.G. Prado, 1995, Automatic maceral and reflectance analysis in single seam bituminous coals, in J.A. Pajares and J.M.D. Tascon, eds., Coal science, v. 1: New York, Elsevier, Coal Science and Technology 24, p. 239-242.Catalina, J.C., D. Alarcón, and J.G. Prado, 1995, Automatic maceral and reflectance analysis in single seam bituminous coals, in J.A. Pajares and J.M.D. Tascon, eds., Coal science: New York, Elsevier, Coal Science and Technology 24, v. 1, p. 239-242.

Cathyl-Bickford, C.G., 1991, Coal geology and coalbed methane potential of Comox and Nanaimo coal fields, Vancouver Island, British Columbia, in S.D. Schwochow, D.K. Murray, and M.F. Fahy, eds., Coalbed methane of western North America: Denver, CO, Rocky Mountain Association of Geologists Guidebook, p. 155-162.

Cecil, C.B., and J.H. Medlin, 1987, Coal basin analysis and synthesis, in Coal exploration, evaluation and exploitation: ESCAP Series on Coal, v. 5, p. 33-36.Cecil, C.B., F.T. Dulong, J.C. Cobb, and Supardi, 1993, Allogenic and autogenic controls on sedimentation in the central Sumatra Basin ad an analogue for Pennsylvanian coal-bearing strata in the Appalachian Basin, in J.C. Cobb and C.B. Cecil, eds., Modern and ancient coal-forming environments: Geological Society of America Special Paper 286, p. 3-22.Cecil, C.B., J.J. Renton, R.W. Stanton, and F.T. Dulong, 1979, Some geologic factors controlling mineral matter in coal, in A.C. Donaldson, M.W. Presley, and J.J. Renton, eds., Carboniferous coal short course and guidebook: West Virginia Geological and Economic Survey, Bulletin B-37-1, p. 224-239.Cecil, C.B., R.W. Stanton, F.T. Dulong, and J.J. Renton, 1979, Geologic factors that control mineral matter in coal, in A.C. Donaldson, M.W. Presley, and J.J. Renton, eds., Carboniferous coal short course and guidebook: West Virginia Geological and Economic Survey, Bulletin B-37-3, p. 43-56.Cecil, C.B., R.W. Stanton, F.T. Dulong, and J.J. Renton, 1979, Geologic factors that control mineral matter in coal, in A.C. Donaldson, M.W. Presley, and J.J. Renton, eds., Carboniferous coal short course and guidebook: West Virginia Geological and Economic Survey, Bulletin B-37-3, p. 43-56.Cecil, C.B., R.W. Stanton, F.T. Dulong, and J.J. Renton, 1982, Geologic factors that control mineral matter in coal, in B.S. Filby, B.S. Carpenter, and R.C. Ragaini, eds., Atomic and nuclear methods in fossil fuel research: New York, Plenum Press, p. 323-335.

Cecil, C.B., R.W. Stanton, S.G. Neuzil, F.T. Dulong, L.F. Ruppert, and B.S. Pierce, 1985, Paleoclimate controls on late Paleozoic sedimentation and peat formation in the central Appalachian Basin (U.S.A.), in T.L. Phillips and C.B. Cecil, eds., Paleoclimate controls on coal resources of the Pennsylvanian System of North America: International Journal of Coal Geology, v. 5, p. 195-230.

Chadwick, R.A., and D.J. Noy, 2010, History-matching flow simulations and time-lapse seismic data from the Sleipner CO2 plume, in B.A. Vining and S.C. Pickering, eds., Petroleum geology: from mature basins to new frontiers: London, Geological Society, Proceedings of the 7 th Petroleum Geology Conference, p. 1171-1182.

Chakrabartty, S.K., and M.P. du Plessis, 1985, Evaluation of Alberta Plains coals for pyrolysis and liquefaction processes: Alberta Research Council, Coal Report 85-1, 24 p.Chakrabartty, S.K., J.F. Fryer, and J.D. Campbell, 1981, Pyrolytic properties of Alberta coals: Alberta Research Council Information Series 99, 11 p.Chalmers, G.R.L., and R.M. Bustin, 2007, On the effects of petrographic composition on coalbed methane sorption: International Journal of Coal Geology, v. 69, p. 288-304.Chalmers, G.R.L., and R.M. Bustin, 2007, The organic matter distribution and methane capacity of the Lower Cretaceous strata of northeastern British Columbia, Canada: International Journal of Coal Geology, v. 70, p. 223-239.Chalmers, G.R.L., R. Boyd, and C.F.K. Diessel, 2013, Accommodation-based coal cycles and significant surface correlation of low-accommodation Lower Cretaceous coal seams, Lloydminster heavy oil field, Alberta, Canada: Implications for coal quality distribution: AAPG Bulletin, v. 97, p. 1347-1369.Chaloner, W.G., 1989, Fossil charcoal as an indicator of palaeoatmospheric oxygen level: Journal of the Geological Society of London, v. 146, part 1, p. 171-174.Chaloner, W.G., 1989, Fossil charcoal as an indicator of palaeoatmospheric oxygen level: Journal of the Geological Society of London, v. 146, part 1, p. 171-174.Chance, D.L., 2008, Louisiana CBM on the cusp?: An Investor’s Guide to Unconventional Gas: Shales and Coalbed Methane, Supplement to Oil & Gas Investor, January 2008, p. 30-31.Chandra, D., 1958, Reflectance of oxidized coals: Economic Geology, v. 53, p. 102-108.Chandra, D., 1962, Reflectance and microstructure of weathered coals: Fuel, v. 41, p. 185-193.Chandra, D., 1965, Use of reflectance in evaluating temperature of carbonized or thermally metamorphosed coals: Fuel, v. 44, p. 171-176.Chandra, D., 1966, Effect of storage of coals on reflectance and petrological composition: Economic Geology, v. 61, p. 754-759.Chandra, D., and Y.V.S. Prasad, 1990, Effect of coalification on spontaneous combustion of coals: International Journal of Coal Geology, v. 16, p. 225-229.Chang, E., 2008, CNX: a CBM and shale gas play: An Investor’s Guide to Unconventional Gas: Shales and Coalbed Methane, Supplement to Oil & Gas Investor, January 2008, p. 20-22.Chang, S., and R.A. Berner, 1998, Humic substance formation via the oxidative weathering of coal: Environmental Science and Technology, v. 32, p. 2883-2886.Chang, S., and R.A. Berner, 1999, Coal weathering and the geochemical carbon cycle: Geochimica et Cosmochimica Acta, v. 63, p. 3301-3310.

Chao, E.C.T., J.A. Minkin, and C.L. Thompson, 1982, Application of automated image analysis to coal petrology: International Journal of Coal Geology, v. 2, p. 113-150.Chapman, J., 2004, Carbon dioxide alchemy: Geotimes, v. 49, no. 12, p. 10-11.Chareonsuppanimit, P., S.A. Mohammad, R.L. Robinson, Jr., and K.A.M. Gasem, 2012, High-pressure adsorption of gases on shales: Measurements and modeling: International Journal of Coal Geology, v. 95, p. 34-46.Chareonsuppanimit, P., S.A. Mohammad, R.L. Robinson, Jr., and K.A.M. Gasem, 2012, High-pressure adsorption of gases on shales: Measurements and modeling: International Journal of Coal Geology, v. 95, p. 34-46.Chareonsuppanimit, P., S.A. Mohammad, R.L. Robinson, Jr., and K.A.M. Gasem, 2014, Modeling gas-adsorption-induced swelling and permeability changes in coals: International Journal of Coal Geology, v. 121, p. 98-109.

Charrière, D., Z. Pokryszka, and P. Behra, 2010, Effect of pressure and temperature on diffusion of CO2 and CH4 into coal from the Lorraine Basin (France): International Journal of Coal Geology, v. 81, p. 373-380.Charrière, D., Z. Pokryszka, and P. Behra, 2010, Effect of pressure and temperature on diffusion of CO2 and CH4 into coal from the Lorraine Basin (France): International Journal of Coal Geology, v. 81, p. 373-380.Chatterjee, R., and S. Paul, 2013, Classification of coal seams for coal bed methane exploitation in central part of Jharia coalfield, India—A statistical approach: Fuel, v. 111, p. 20-29.Chaturvedi, T., J.M. Schembre, and A.R. Kovscek, 2009, Spontaneous imbibition and wettability characteristics of Powder River Basin coal: International Journal of Coal Geology, v. 77, p. 34-42.Chatziapostolou, A., S. Kalaitzidis, S. Papazisimou, K. Christanis, and D. Vagias, 2006, Mode of occurrence of trace elements in the Pellana lignite (SE Peloponnese, Greece): International Journal of Coal Geology, v. 65, p. 3-16.Chaudhuri, S.G., and S. Ghose, 1990, Fluorescence technique—its application for better prediction of properties for certain Indian coals: International Journal of Coal Geology, v. 14, p. 237-253.Chehreh Chelgani, S., S. Mesroghli, and J.C. Hower, 2010, Simultaneous prediction of coal rank parameters based on ultimate analysis using regression and artificial neural network: International Journal of Coal Geology, v. 83, p. 31-34.Chehreh Chelgani, S., S. Mesroghli, and J.C. Hower, 2010, Simultaneous prediction of coal rank parameters based on ultimate analysis using regression and artificial neural network: International Journal of Coal Geology, v. 83, p. 31-34.Chen, D., J.-Q. Shi, S. Durucan, and A. Korre, 2014, Gas and water relative permeability in different coals: Model match and new insights: International Journal of Coal Geology, v. 122, p. 37-49.Chen, D., Z. Pan, J. Liu, and L.D. Connell, 2013, An improved relative permeability model for coal reservoirs: International Journal of Coal Geology, v. 109-110, p. 45-57.Chen, J., G. Liu, M. Jiang, C.-L. Chou, H. Li, B. Wu, L. Zheng, and D. Jiang, 2011, Geochemistry of environmentally sensitive trace elements in Permian coals from the Huainan coalfield, Anhui, China: International Journal of Coal Geology, v. 88, p. 41-54.Chen, X.D., and J.B. Stott, 1993, The effect of moisture content on the oxidation rate of coal during near-equilibrium drying and wetting at 50ºC: Fuel, v. 72, p. 787-792.

Chen, Y.G., J.S. Gao, and H.H. Oelert, 1988, Coprocessing of Chinese bituminous coals. 1. Survey: Erdöl und Kohle-Erdgas-Petrochemie, v. 41, no. 7-8, p. 300-302.Chen, Z., J. Liu, D. Elsworth, L.D. Connell, and Z. Pan, 2010, Impact of CO2 injection and differential deformation on CO2 injectivity under in-situ stress conditions: International Journal of Coal Geology, v. 81, p. 97-108.Chen, Z., J. Liu, D. Elsworth, L.D. Connell, and Z. Pan, 2010, Impact of CO2 injection and differential deformation on CO2 injectivity under in-situ stress conditions: International Journal of Coal Geology, v. 81, p. 97-108.Cheng, A.-L., and W.-L. Huang, 2004, Selective adsorption of hydrocarbon gases on clays and organic matter: Organic Geochemistry, v. 35, p. 413-423.

Chang, Y.-J., W.-L. Huang, A. Hsu, and S.-Y. L. Huang, 2008, Characterization of kerogens and coals using fluorescence measured in situ at elevated temperatures: International Journal of Coal Geology, v. 75, p. 63-75.

Charpentier, R.R., W. de Witt, Jr., G.E. Claypool, L.D. Harris, R.F. Mast, J.D. Megeath, J.B. Roen, and J.W. Schmoker, 1993, Estimates of unconventional natural gas resources of the Devonian shales of the Appalachian Basin, in J.B. Roen and R.C. Kepferle, eds., Petroleum geology of the Devonian and Mississippian black shale of eastern North America: U.S. Geological Survey Bulletin 1909, p. N1-N14.

Chen, Y., S. Mori, and W.-P. Pan, 1995, Ignition mechanisms of different ranks of coal, in J.A. Pajares and J.M.D. Tascon, eds., Coal science: New York, Elsevier, Coal Science and Technology 24, v. 1, p. 603-606.

Chesnut, D.R., Jr., 1994, Eustatic and tectonic control of deposition of the Lower and Middle Pennsylvanian strata of the central Appalachian Basin, in J.M. Dennison and F.R. Ettensohn, eds., Tectonic and eustatic controls on sedimentary cycles: SEPM Concepts in Sedimentology and Paleontology, v. 4, p. 51-64.

Cheung, K., H. Sanei, P. Klassen, B. Mayer, and F. Goodarzi, 2009, Produced fluids and shallow groundwater in coalbed methane (CBM) producing regions of Alberta, Canada: Trace element and rare earth element geochemistry: International Journal of Coal Geology, v. 77, p. 338-349.Cheung, K., H. Sanei, P. Klassen, B. Mayer, and F. Goodarzi, 2009, Produced fluids and shallow groundwater in coalbed methane (CBM) producing regions of Alberta, Canada: Trace element and rare earth element geochemistry: International Journal of Coal Geology, v. 77, p. 338-349.Cheung, K., H. Sanei, P. Klassen, B. Mayer, and F. Goodarzi, 2009, Produced fluids and shallow groundwater in coalbed methane (CBM) producing regions of Alberta, Canada: Trace element and rare earth element geochemistry: International Journal of Coal Geology, v. 77, p. 338-349.Cheung, K., P. Klassen, B. Mayer, F. Goodarzi, and R. Aravena, 2010, Major ion and isotope geochemistry of fluids and gases from coalbed methane and shallow groundwater wells in Alberta, Canada: Applied Geochemistry, v. 25, p. 1307-1329.Cheung, K., P. Klassen, B. Mayer, F. Goodarzi, and R. Aravena, 2010, Major ion and isotope geochemistry of fluids and gases from coalbed methane and shallow groundwater wells in Alberta, Canada: Applied Geochemistry, v. 25, p. 1307-1329.Chi, G., R. Bertrand, and D. Lavoie, 2000, Regional-scale variation of characteristics of hydrocarbon fluid inclusions and thermal conditions along the Paleozoic Laurentian continental margin in eastern Quebec, Canada: Bulletin of Canadian Petroleum Geology, v. 48, p. 193-211.Chi, W., and L. Yang, 2001, Feasibility of coalbed methane exploitation in China: Journal of Petroleum Technology, v. 53, no. 9, p. 74.Chidsey, T.C., Jr., 2007, Geological sequestration of carbon dioxide and enhanced oil recovery: Utah Geological Survey, Survey Notes, v. 39, no. 2, p. 4-7.

Chigira, M., and T. Oyama, 2000, Mechanism and effect of chemical weathering of sedimentary rocks: Engineering Geology, v. 55, p. 3-14.Chilingarian, G.V., and T.F. Yen, eds., 1978, Bitumens, asphalts, and tar sands: New York, Elsevier Scientific Publishing Co., Developments in Petroleum Science 7, 331 p.Ching-Yi, T., C. Yih-Fong, W. Spackman, and A.W. Scaroni, 1984, Correlation of microstrength and industrial drum strength indices of metallurgical cokes: Fuel, v. 63, p. 866-868.Chiu, Y.F., 1982, Study of coke petrography and factors affecting coke reactivity: Ironmaking and Steelmaking, v. 9, p. 193-199.

Choi, S.K., and M.B. Wold, 2001, Advances in simulation of gas outburst conditions in underground coal mines: Tuscaloosa, Alabama, Proceedings, International Coalbed Methane Symposium, Paper 126, p. 283-294.Chou, C.-L., 1984, Relationship between geochemistry of coal and the nature of strata overlying the Herrin coal in the Illinois Basin, U.S.A.: Memoir of the Geological Society of China, no. 6, p. 269-280. (Illinois State Geological Survey Reprint 1985L)

Chou, C.-L., 2012, Sulfur in coals: A review of geochemistry and origins: International Journal of Coal Geology, v. 100, p. 1-13.Chou, C.-L., R.B. Finkelman, A. Kolker, and B. Zheng, eds., 1999, Geochemistry of coal and its impact on the environment and human health: International Journal of Coal Geology, v. 40, p. 83-254.Choudhury, N., P. Boral, T. Mitra, A.K. Adak, A. Choudhury, and P. Sarkar, 2007, Assessment of nature and distribution of inertinite in Indian coals for burning characteristics: International Journal of Coal Geology, v. 72, p. 141-152.Choudhury, N., S. Biswas, P. Sarkar, M. Kumar, S. Ghosal, T. Mitra, A. Mukherjee, and A. Choudhury, 2008, Influence of rank and macerals on the burnout behaviour of pulverized Indian coal: International Journal of Coal Geology, v. 74, p. 145-153.Chowdhurry, A.H., M.G. Fowler, and J.P.A. Noble, 1991, Petroleum geochemistry and geology of the Albert Formation Moncton subbasin, New Brunswick, Canada: Bulletin of Canadian Petroleum Geology, v. 39, p. 315-331.Christanis, K., 1994, The genesis of the Nissi peatland (northwestern Greece) as an example of peat and lignite deposit formation in Greece: International Journal of Coal Geology, v. 26, p. 63-77.Christanis, K., 2004, Coal facies studies in Greece: International Journal of Coal Geology, v. 58, p. 99-106.Christie, R., and S. Campbell, 2007, Micro imaging key in CBM development: American Oil & Gas Reporter, v. 50, no. 11, p. 60-65.Christophel, D.C., and D.R. Greenwood, 1989, Changes in climate and vegetation in Australia during the Tertiary: Review of Palaeobotany and Palynology, v. 58, p. 95-109.Chu, W., and M. Sujatmiko, 2009, Coal seam oxidation leads to CP failure, pipeline corrosion: Oil & Gas Journal, v. 107.44, p. 58-65.Chugh, Y.P., B.M. Sangunett, and K.C. Vories, eds., 1996, Proceedings of coal combustion by-products associated with coal mining: interactive forum: Southern Illinois University at Carbondale, October 29-31, 1996, 303 p.Chyi, L.L., 1997, Groundwater transformation of a low-sulfur to a high-sulfur coal, the Harlem coal of the northern Appalachian Basin: International Journal of Coal Geology, v. 33, p. 317-331.Chyi, L.L., and C.-L. Chou, eds., 1990 Recent advances in coal geochemistry: Geological Society of America Special Paper 248, 99 p.Cienfuegos, P., and J. Loredo, 2010, Coalbed methane resources assessment in Asturias (Spain): International Journal of Coal Geology, v. 83, p. 366-376.Ciu, X., R.M. Bustin, and G. Dipple, 2004, Selective transport of CO2, CH4 and N2 in coals: insight from modeling of experimental gas adsorption data: Fuel, v. 83, p. 293-303.Clark, D.T., and R. Wilson, 1984, Some aspects of the surface chemistry of coal, kerogen and bitumen as revealed by ESCA: Organic Geochemistry, v. 6, p. 455-461.Clark, J., 2004, Far East Energy pressing big CBM schemes in China: Oil & Gas Journal, v. 102.33, p. 24-26.Clark, J.R., 2006, Clean coal urged for CO2 control, energy security: Oil & Gas Journal, v. 104.16, p. 35-38.Clark, J.R., 2007, Task force: US can shrink oil gap with unconventional fuels: Oil & Gas Journal, v. 105.41, p. 20-26.

Chesnut, D.R., Jr., J.C. Cobb, and S.F. Greb, 1993, Cyclothems of the central Appalachian Basin: a modern analog from Indonesia: 12 th International Congress of Stratigraphy and Geology of the Carboniferous and Permian, Comptes Rendus, v. 2, p. 431-436.

Chidsey, T.C., Jr., 2012, Oil shale vs. shale oil: what’s the difference?: Utah Geological Survey, Survey Notes, v. 44, no. 3, p. 6-7. http://geology.utah.gov/surveynotes/snt44-3.pdf

Choate, R., C.A. Johnson, and J.P. McCord, 1984, Geologic overview, coal deposits, and potential for methane recovery from coalbeds—Powder River Basin, in C.T. Rightmire, G.E. Eddy, and J.N. Kirr, eds., Coalbed methane resources of the United States: AAPG Studies in Geology 17, p. 335-351.Choate, R., C.A. Johnson, and J.P. McCord, 1984, Geologic overview, coal, and coalbed methane resources of the western Washington coal region, in C.T. Rightmire, G.E. Eddy, and J.N. Kirr, eds., Coalbed methane resources of the United States: AAPG Studies in Geology 17, p. 353-372.Choate, R., D. Jurich, and G.J. Saulnier, Jr., 1984, Geologic overview, coal deosits, and potential for methane recovery from coalbeds, Piceance Basin—Colorado, in C.T. Rightmire, G.E. Eddy, and J.N. Kirr, eds., Coalbed methane resources of the United States: AAPG Studies in Geology 17, p. 223-251.Choate, R., J. Lent, and C.T. Rightmire, 1984, Upper Cretaceous geology, coal, and the potential for methane recovery from coalbeds in San Juan Basin—Colorado and New Mexico, in C.T. Rightmire, G.E. Eddy, and J.N. Kirr, eds., Coalbed methane resources of the United States: AAPG Studies in Geology 17, p. 185-222.Choate, R., J.P. McCord, and C.T. Rightmire, 1986, Assessment of natural gas from coalbeds by geologic characterization and production evaluation, in D.D. Rice, ed., Oil and gas assessment; methods and applications: AAPG Studies in Geology 21, p. 223-245.

Chou, C.-L., 1990, Geochemistry of sulfur in coal, in W.L. Orr and C.M. White, eds., Geochemistry of sulfur in fossil fuels: Washington, D.C., American Chemical Society Symposium Series 429, p. 30-52.

Clark, J.R., 2008, Nuclear heat advances oil shale refining in situ: Oil & Gas Journal, v. 106.30, p. 22-24.

Clarke, L., 1992, Applications for coal-use residues: IEA Coal Research, IEACR/50, 406 p.Clarke, L.B., and L. Sloss, 1992, Trace elements—emission from coal combustion and gasification: IEA Coal Research, IEACR/49, 111 p.Clarkson, C.R., 2013, Production data analysis of unconventional gas wells: Review of theory and best practices: International Journal of Coal Geology, v. 109-110, p. 101-146.Clarkson, C.R., 2013, Production data analysis of unconventional gas wells: Workflow: International Journal of Coal Geology, v. 109-110, p. 147-157.Clarkson, C.R., and R.M. Bustin, 1996, Variation in micropore capacity and size distribution with composition in bituminous coal of the western Canadian sedimentary basin: Fuel, v. 75, p. 1483-1498.Clarkson, C.R., and R.M. Bustin, 1997, Variation in permeability with lithotype and maceral composition of Cretaceous coals of the Canadian Cordillera: International Journal of Coal Geology, v. 33, p. 135-151.Clarkson, C.R., and R.M. Bustin, 1997, Variation in permeability with lithotype and maceral composition of Cretaceous coals of the Canadian Cordillera: International Journal of Coal Geology, v. 33, p. 135-151.Clarkson, C.R., and R.M. Bustin, 1999, The effect of pore structure and gas pressure upon the transport properties of coal: a laboratory and modelling study: 1. Isotherms and pore volume distributions: Fuel, v. 78, p. 1333-1344.Clarkson, C.R., and R.M. Bustin, 2000, Binary gas adsorption/desorption isotherms: effect of moisture and coal composition upon carbon dioxide selectivity over methane: International Journal of Coal Geology, v. 42, p. 241-271.Clarkson, C.R., M. Rahmanian, A. Kantzas, and K. Morad, 2011, Relative permeability of CBM reservoirs: Controls on curve shape: International Journal of Coal Geology, v. 88, p. 204-217.Clarkson, C.R., M.N. Lamberson, and R.M. Bustin, 1993, Variation in surface area and micropore size distribution with composition of medium volatile bituminous coal of the Gates Formation, northeastern British Columbia: implications for coalbed methane potential: Current Research, Part E, Geological Survey of Canada Paper 93-1, p. 97-104.Clarkson, C.R., R.M. Bustin, and J.H. Levy, 1997, Application of the mono/multilayer and adsorption potential theories t coal methane adsorption isotherms at elevated temperature and pressure: Carbon, v. 35, p. 1689-1705.Clausen, C.-D. and M. Teichmuller, 1982, Die bedeutung der Graptolithenfragmente im Palaozoikum von Soest-Erwitte fur stratigraphie und inkohlung: Fortschritte in der Geologie von Rheinland und Westfalen, v. 30, p. 145-167.

Clayton, J.L., and J.D. King, 1987, Effects of weathering on biological marker and aromatic hydrocarbon composition of organic matter in Phosphoria shale outcrop: Geochimica et Cosmochimica Acta, v. 51, p. 2153-2157.Clayton, J.L., and P.J. Swetland, 1978, Subaerial weathering of sedimentary organic matter: Geochimica et Cosmochimica Acta, v. 42, p. 305-312.

Clayton, J.L., D.D. Rice, and G.E. Michaels, 1991, Oil-generating coals of the San Juan Basin, New Mexico and Colorado, U.S.A: Organic Geochemistry, v. 17, p. 735-742.

Clemens, A.H., T.W. Matheson, and D.E. Rogers, 1990, DTA studies of the low temperature oxidation of low rank coals: Fuel, v. 69, p. 255-256.Clemens, A.H., T.W. Matheson, and D.E. Rogers, 1991, Low-temperature oxidation studies of dried New Zealand coals: Fuel, v. 70, p. 215-221.Clemens, T., D. Gong, and S. Pearce, 2006, Study on the suitability of New Zealand coals for hydrogen production: International Journal of Coal Geology, v. 65, p. 235-242.Clemente, J.S., and M.J. Simpson, 2013, Physical protection of lignin by organic matter and clay minerals from chemical oxidation: Organic Geochemistry, v. 58, p. 1-12.Clementz, D.M., 1979, Effect of oil and bitumen saturation on source-rock pyrolysis: AAPG Bulletin, v. 63, p. 2227-2232.Cloke, M., and E. Lester, 1994, Characterization of coals for combustion using petrographic analysis: a review: Fuel, v. 73, p. 315-320.Cloke, M., E. Lester, M. Allen, and N.J. Miles, 1995, Automated maceral analysis using fluorescence microscopy and image analysis: Fuel, v. 74, p. 659-669.Close, J.C., 1992, Western Cretaceous coal seam project: Quarterly Review of Methane from Coal Seams Technology, v. 10, no. 1, p. 11-15.

Close, J.C., and T.M. Erwin, 1989, Significance and determination of gas content data as related to coalbed methane reservoir evaluation and production implications: Proceedings of the 1989 Coalbed Methane Symposium, paper 8922, p. 37-55.Clough, J.G., 2001, Coalbed methane—potential energy source for rural Alaska: State of Alaska Division of Geological and Geophysical Surveys, Alaska GeoSurvey News, v. 5, no. 2, p. 1-4.Clouser, G., 2006, Powder River Basin CBM production still growing: An investor’s guide to coalbed methane, A supplement to Oil and Gas Investor, v. 26, no. 12, p. 8-12.Clouser, G., 2006, Water management a key concern: An investor’s guide to coalbed methane, A supplement to Oil and Gas Investor, v. 26, no. 12, p. 13-18.Clouser, G., 2008, Green light at Atlantic Rim: An Investor’s Guide to Unconventional Gas: Shales and Coalbed Methane, Supplement to Oil & Gas Investor, January 2008, p. 38-40.

Clark, W.F., and T. Hemler, 1988, Completing, equipping, and operating Fruitland Formation coal-bed methane wells in the San Juan basin, New Mexico and Colorado, in J.E. Fassett, ed., Geology and coal-bed methane resources of the northern San Juan basin, Colorado and New Mexico: Denver, Rocky Mountain Association of Geologists Guidebook, p. 125-132.

Claypool, G.E., and L.B. Magoon, 1988, Oil and gas source rocks in the National Petroleum Reserve in Alaska, in G. Cryc, ed., Geology and exploration of the National Petroleum Reserve in Alaska, 1974-1982: USGS Professional Paper 1399, p. 451-481.Clayton, J. L., J. S. Leventhal, D. D. Rice, J. C. Pashin, B. Mosher, and P. Czepiel, 1994, Atmospheric methane flux from coals—preliminary investigation of coal mines and geologic structures in the Black Warrior basin, Alabama, in D.G. Howell, ed., The future of energy gases: U.S. Geological Survey Professional Paper 1570, p. 471-492.Clayton, J.L., 1993, Composition of crude oils generated from coals and coaly organic matter in shales, in B.E. Law and D.D. Rice, eds., Hydrocarbons from coal: AAPG Studies in Geology 38, p. 185-201.Clayton, J.L., 1998, Geochemistry of coalbed gas — a review, in R.M. Flores, ed., Coalbed methane: from coal-mine outbursts to a gas resource: International Journal of Coal Geology, v. 35, p. 159-173.

Clayton, J.L., D.D. Rice, and G.E. Michael, 1991, Oil-generating coals of the San Juan basin, New Mexico and Colorado, U.S.A., in P.K. Mukhopadhyay, M.G. Fowler, and W.G. Dow, eds., Selected papers from the symposium on coal and terrestrial organic matter as a source rock for petroleum: Organic Geochemistry, v. 17, p. 735-742.

Clemens, A.H., and T.W. Matheson, 1995, Spontaneous heating in New Zealand coals, in J.A. Pajares and J.M.D. Tascon, eds., Coal science: New York, Elsevier, Coal Science and Technology 24, v. 1, p. 481-484.

Close, J.C., 1993, Natural fractures in coal, in B.E. Law and D.D. Rice, eds., Hydrocarbons from coal: AAPG Studies in Geology 38, p. 119-132.Close, J.C., 1993, Natural fractures in coal, in B.E. Law and D.D. Rice, eds., Hydrocarbons from coal: AAPG Studies in Geology 38, p. 119-132.Close, J.C., and M.J. Mavor, 1991, Influence of coal composition and rank on fracture development in Fruitland coal gas reservoirs of San Juan basin, in S.D. Schwochow, D.K. Murray, and M.F. Fahy, eds., Coalbed methane of western North America: Denver, Rocky Mountain Association of Geologists, p. 109-121.Close, J.C., and R.R. Dutcher, 2002, Geomorphology of drainage patterns: clues to coal gas natural fracture timing, orientation and location, Raton basin, Colorado–New Mexico, in S.D. Schwochow and V.F. Nuccio, eds., Coalbed methane of North America, II: Rocky Mountain Association of Geologists, p. 25-48.

Coates, J., 2003, A review of coalbed methane operational issues in the Cherokee Basin, Kansas and Oklahoma: a case study (abstract): AAPG Mid-Continent Section Meeting, Official Program Book, p. 28.

Cobb, J.C., and C.B. Cecil, eds., 1993, Modern and ancient coal-forming environments: Geological Society of America Special Paper 286, 202 p.Cobb, J.C., and C.B. Cecil, eds., 1993, Modern and ancient coal-forming environments: Geological Society of America Special Paper 286, 202 p.Cobb, J.C., J.D. Steele, C.G. Treworgy, and J.F. Ashby, 1980, The abundance of zinc and cadmium in sphalerite-bearing coals in Illinois: Illinois State Geological Survey, Illinois Minerals Note 74, 28 p.Cobb, J.C., J.D. Steele, C.G. Treworgy, and J.F. Ashby, 1980, The abundance of zinc and cadmium in sphalerite-bearing coals in Illinois: Illinois State Geological Survey, Illinois Minerals Note 74, 28 p.Cobb, J.C., J.M. Masters, C.G. Treworgy, and R.J. Helfinstine, 1979, Abundance and recovery of sphalerite and fine coal from mine waste in Illinois: Illinois State Geological Survey, Illinois Minerals Note 71, 11 p.

Cody, G.D., and G. Sághi-Szabó, 1999, Calculation of the 13C NMR chemical shift of ether linkages in lignin derived geopolymers: constraints on the preservation of lignin primary structure with diagenesis: Geochimica et Cosmochimica Acta, v. 63, p. 193-205.Cohen, A.D., 1968, Petrology of some peats of southern Florida: with special reference to the origin of coal: State College, Pennsylvania State University, unpublished PhD thesis, 352 p.Cohen, A.D., 1970, An allochthonous peat deposit from southern Florida: Geological Society of America Bulletin, v. 81, p. 2477-2482.Cohen, A.D., 1973, Petrology of some Holocene peat sediments from the Okefenokee swamp-marsh complex of southern Georgia: Geological Society of America Bulletin, v. 84, p. 3867-3878.Cohen, A.D., 1974, Evidence of fires in the ancient Everglades and coastal swamps of southern Florida: Miami Geological Society Memoir 2, p. 213-218.Cohen, A.D., 1974, Petrography and paleoecology of Holocene peats from the Okefenokee swamp-marsh complex of Georgia: Journal of Sedimentary Petrology, v. 44, p. 716-726.Cohen, A.D., 1975, Peats from the Okefenokee swamp-marsh complex: Geoscience and Man, v. 11, p. 123-131.

Cohen, A.D., and A.M. Bailey, 1997, Petrographic changes induced by artificial coalfication of peat: comparison of two planar facies (Rhizophora and Cladium) from the Everglades-Mangrove complex of Florida and a dome facies (Cyrilla) from the Okefenokee Swamp of Georgia: International Journal of Coal Geology, v. 34, p. 163-194.Cohen, A.D., and E.M. Stack, 1996, Some observations regarding the potential effects of doming of tropical peat deposits on the composition of coal beds: International Journal of Coal Geology, v. 29, p. 39-65. (erratum, v. 30, p. 271)Cohen, A.D., and F.J. Rich, 1991, Preliminary trends in reflectance and maceral analysis of Upper Cretaceous Menefee and Crevasse Canyon coals in the San Juan basin of New Mexico: Organic Geochemistry, v. 17, p. 205-209.

Cohen, A.D., and W. Spackman, 1972, Methods in peat petrology and their application to reconstruction of paleoenvironments: Geological Society of America Bulletin, v. 83, p. 129-141.Cohen, A.D., and W. Spackman, 1974, The petrology of peats from the Everglades and coastal swamps of southern Florida: Miami Geological Society Memoir 2, p. 233-255.Cohen, A.D., and W. Spackman, 1977, Phytogenic organic sediments and sedimentary environments in the Everglades-Mangrove complex, part II. Origin, description, and classification of the peats of south Florida: Palaeontographica, v. 162, part B, p. 71-114.Cohen, A.D., and W. Spackman, 1980, Phytogenic organic sediments and sedimentary environments in the Everglades-Mangrove complex of Florida, part III. The alteration of plant material in peats and the origin of coal macerals: Palaeontographica, Abt. B, v. 172, p. 125-149.Cohen, A.D., and W. Spackman, 1980, Phytogenic organic sediments and sedimentary environments in the Everglades-Mangrove complex of Florida, part III. The alteration of plant material in peats and the origin of coal macerals: Palaeontographica, v. 172, part B, p. 125-149.Cohen, A.D., C.P. Cage, and W.S. Moore, 1999, Combining organic petrography and palynology to assess anthropogenic impacts on peatlands. Part 1. An example from the northern Everlades of Florida: International Journal of Coal Geology, v. 39, p. 3-45.Cohen, A.D., C.P. Cage, W.S. Moore, and R.S. VanPelt, 1999, Combining organic petrography and palynology to assess anthropogenic impacts on peatlands. Part 2. An example from a Carolina Bay wetland at the Savannah River site in South Carolina: International Journal of Coal Geology, v. 39, p. 47-95.Cohen, A.D., D.J. Casagrande, M.J. Andrejko, and G.R. Best, eds., 1984, The Okefenokee swamp: its natural history, geology, and geochemistry: Columbia, South Carolina, Wetland Surveys,Cohen, A.D., M.S. Rollins, J.R. Durig, and R. Raymond, Jr., 1991, Development of a peat sample bank: Journal of Coal Quality, v. 10, no. 4, p. 145-151.Cohen, A.D., R. Raymond, Jr., L.M. Archuleta, and D.A. Mann, 1987, Preliminary study of the reflectance of huminite macerals in recent surface peats: Organic Geochemistry, v. 11, p. 429-430.Cohen, A.D., W. Spackman, and P. Dolsen, 1984, Occurrence and distribution of sulfur in peat-forming environments of southern Florida: International Journal of Coal Geology, v. 4, p. 73-96.Cohen, A.D., W. Spackman, and P. Dolsen, 1984, Occurrence and distribution of sulfur in peat-forming environments of southern Florida: International Journal of Coal Geology, v. 4, p. 73-96.

Cohen, D.M., 2007, Coalbed methane activity cools off: World Oil, v. 228, no. 8, p. 91-94.Cohen, D.M., 2008, Coalbed methane expansion stalls: World Oil, v. 229, no. 8.Cohen, D.M., 2009, US coalbed methane takes a dive: World Oil, v. 230, no. 8, p. 71-72.

Colbath, G.K., and H.R. Grenfell, 1995, Review of biological affinities of Paleozoic acid-resistant, organic-walled eukaryotic algal microfossils (including "acritarchs"): Review of Palaeobotany and Palynology, v. 86, p. 287-314.Cole, G.A., 1994, Graptolite-chitinozoan reflectance and its relationship to other geochemical maturity indicators in the Silurian Qusaiba Shale, Saudi Arabia: Energy and Fuels, v. 8, p. 1443-1459.

Cobb, J.C., 1985, Timing and development of mineralized veins during diagenesis in coal beds, in Compte Rendu of IXICC: SIU Press, Carbondale, v. 4, p. 371-376.

Cody, G.D., and G. Sághi-Szabó, 1999, Calculation of the 13C NMR chemical shift of ether linkages in lignin derived geopolymers: constraints on the preservation of lignin primary structure with diagenesis: Geochimica et Cosmochimica Acta, v. 63, p. 193-205.

Cohen, A.D., 1983, Micropetrographic characterization of peats, in C.H. Fuchsman and S.A. Spigarelli, eds., International symposium on peat utilization: Bemidji, Minnesota, Center for Environmental Studies, Bemidji State University, p. 431-443.Cohen, A.D., 1983, Obtaining more precise descriptions of peats by use of oriented microtome sections, in P.M. Jarrett, ed., Testing of peats and organic soils: ASTM Special Technical Publication (STP) 820, p. 21-36.Cohen, A.D., 1984, The Okefenokee swamp: a low sulphur end-member of a shoreline-related depositional model for coastal plain coals, in R.A. Rahmani and R.M. Flores, eds., Sedimentology of coal and coal-bearing sequences: International Association of Sedimentologists, Special Publication 7, Boston, Blackwell Scientific Publications, p. 231-240.

Cohen, A.D., and M.J. Andrejko, 1984, Premaceral contents of peats correlated with proximate and ultimate analyses, in R.E. Winans and J.C. Crelling, eds., Chemistry and characterization of coal macerals: ASTM Symposium Series 252, p. 21-32.

Cohen, A.D., W. Spackman, and R. Raymond, Jr., 1987, Interpreting the characteristics of coal seams from chemical, physical and petrographic studies of peat deposits, in A.C. Scott, ed., Coal and coal-bearing strata: recent advances: London, Geological Society Special Publication 32, Boston, Blackwell Scientific Publications, p. 107-125.

Coin, C.D.A., and A.J. Broome, 1997, Coke quality prediction from pilot scale ovens and plant data: Proceedings of the 11 th International Conference on Coal Research, Calgary, p. 325-333.

Coleman, L., L.J. Bragg, and R.B. Finkelman, 1993, Distribution and mode of occurrence of selenium in US coals: Environmental Geochemistry and Health, v. 15, p. 215-227.Collett, T.S., and C.E. Barker, eds., 2003, Coalbed methane in the Ferron coals, Utah: a multidisciplinary study: International Journal of Coal Geology, v. 56, p. 1-201.

Collot, A.-G., 2006, Matching gasification technologies to coal properties: International Journal of Coal Geology, v. 65, p. 191-212.Colmenares, L.B., and M.D. Zoback, 2007, Hydraulic fracturing and wellbore completion of coalbed methane wells in the Powder River Basin, Wyoming: Implications for water and gas production: AAPG Bulletin, v. 91, p. 51-67.Colmenares, L.B., and M.D. Zoback, 2007, Hydraulic fracturing and wellbore completion of coalbed methane wells in the Powder River Basin, Wyoming: Implications for water and gas production: AAPG Bulletin, v. 91, p. 51-67.Colombo, L.E., and O. Ruiz, 1990, Logarithm additivity verification of maximum fluidity for mixes with national raw material: Journal of Coal Quality, v. 9, no. 3, p. 101-104.Colorado School of Mines, 1968, Proceedings of the first five oil shale symposia, 1964-1968: Quarterly of the Colorado School of Mines, v. 59 no. 3, v. 60 no. 3, v. 61 no. 3, v. 62 no. 3, v. 63 no. 4.Combaz, A., 1964, Les palynofacies: Rev. Micropaleont., v. 7, p. 205-218.

Conant, L.C., and V.E. Swanson, 1961, Chattanooga Shale and related rocks of central Tennessee and nearby areas: U.S. Geological Survey Professional Paper 357, 91 p. (see p. 3)Condit, D.D., 1919, Oil shale in western Montana, southeastern Idaho, and adjacent parts of Wyoming and Utah: U.S. Geological Survey Bulletin 711-B, p. 15-40.Condon, S.M., 2003, Fracture network of the Ferron Sandstone member of the Mancos Shale, east-central Utah, USA: International Journal of Coal Geology, v. 56, p. 111-139.Connell, L.D., 2009, Coupled flow and geomechanical processes during gas production from coal seams: International Journal of Coal Geology, v. 79, p. 18-28.Connell, L.D., and C. Detournay, 2009, Coupled flow and geomechanical processes during enhanced coal seam methane recovery through CO2 sequestration: International Journal of Coal Geology, v. 77, p. 222-233.Connell, L.D., and R.G. Jeffery, 2005, History matching for optimization of gas drainage from horizontal wells containing sand propped hydraulic fractures: 2005 International Coalbed Methane Symposium, Tuscaloosa, AL, Paper 0508, 13 p.Connell, L.D., M. Lu, and Z. Pan, 2010, An analytical coal permeability model for tri-axial strain and stress conditions: International Journal of Coal Geology, v. 84, p. 103-114.Connell, L.D., R. Sander, Z. Pan, M. Camilleri, and D. Heryanto, 2011, History matching of enhanced coal bed methane laboratory core flood tests: International Journal of Coal Geology, v. 87, p. 128-138.Connell, L.D., R. Sander, Z. Pan, M. Camilleri, and D. Heryanto, 2011, History matching of enhanced coal bed methane laboratory core flood tests: International Journal of Coal Geology, v. 87, p. 128-138.Conner, C., 2009, Technology optimizes CBM production: American Oil & Gas Reporter, v. 52, no. 8, p. 90-95.

Cook, A.C., A.C. Hutton, and N.R. Sherwood, 1981, Classification of oil shales: Bulletin Des Centres De Recherches Exploration-Production Elf-Aquitaine, v. 5, p. 353-381.Cook, A.C., A.C. Hutton, and N.R. Sherwood, 1981, Classification of oil shales: Bulletin des Centres de Recherches Exploration-Production, Elf Aquitaine, v. 5, p. 353-381.Cook, A.C., and D.G. Murchison, 1977, The accuracy of refractive and absorptive indices derived from reflectance measurements on low-reflectaing materials: Journal of Microscopy, v. 109. pt. 1, p. 29-40.

Cook, A.C., and N.R. Sherwood, 1991, Classification of oil shales, coals, and other organic-rich rocks: Organic Geochemistry, v. 17, p. 211-222.Cook, A.C., and N.R. Sherwood, 1991, Classification of oil shales, coals, and other organic-rich rocks: Organic Geochemistry, v. 17, p. 211-222.Cook, A.C., D.G. Murchison, and E. Scott, 1972, Optically biaxial anthracitic vitrinites: Fuel, v. 51, p. 180-184.Cook, A.C., M. Smyth, and R.G. Vos, 1985, Source potential of Upper Triassic fluvio-deltaic systems of the Exmouth Plateau: APEA Journal, v. 25, pt. 1, p. 204-215.Cook, S.F., 1964, The nature of charcoal excavated at archaeological sites: American Antiquity, v. 29, p. 514-517.Cook, T., 2003, Calculation of estimated ultimate recovery for wells in continuous-type oil and gas accumulations of the Uinta-Piceance Province: International Journal of Coal Geology, v. 56, p. 39-44.Cooper, B.R., and W.A. Ellingson, 1984, The science and technology of coal and coal utilization: New York, Plenum Press, 666 p.

Cooper, J.R., J.C. Crelling, S.M. Rimmer, and A.G. Whittington, 2007, Coal metamorphism by igneous intrusion in the Raton Basin, CO and NM: Implications for generation of volatiles: International Journal of Coal Geology, v. 71, p. 15-27.Cooper, J.R., J.C. Crelling, S.M. Rimmer, and A.G. Whittington, 2007, Coal metamorphism by igneous intrusion in the Raton Basin, CO and NM: Implications for generation of volatiles: International Journal of Coal Geology, v. 71, p. 15-27.

Collinson, M.E., and A.C. Scott, 1987, Implications of vegetational change through the geological record on models for coal-forming environments, in A.C. Scott, ed., Coal and coal-bearing strata: recent advances: London, Geological Society Special Publication 32, p. 67-85.Collinson, M.E., P.F. Van Bergen, A.C. Scott, and J.W. De Leeuw, 1994, The oil-generating potential of plants from coal and coal-bearing strata through time: a review with new evidence from Carboniferous plants, in A.C. Scott and A.J. Fleet, eds., Coal and coal-bearing strata as oil-prone source rocks?: London, The Geological Society Special Publication 77, p. 31-70.

Combaz, A., 1974, La matiere algaire et l'origine du petrole, in B. Tissot and F. Bienner, eds., Advances in organic geochemistry 1973: Paris, Editions Technip, p. 423-438.Combaz, A., 1975, Essai de classification des roches carbonees et des constituants organiques des roches sedimentaires, in B. Alpern, ed., Petrographie de la matiere organique des sediments, relations avec la paleotemperature et le potentiel petrolier: Paris, C.N.R.S., p. 93-101.Combaz, A., 1980, Les kerogenes vus au microscope, in B. Durand, ed., Kerogen - insoluble organic matter from sedimentary rocks: Paris, Editions Technip, p. 55-111.

Cook, A.C., 1980, Optical techniques for the examination of organic matter in oil shales, in A.C. Cook and A. Kantsler, eds., Oil shale petrology workshop: Wollongong, Keiraville Kopiers, p. 1-15.Cook, A.C., 1986, The nature and significance of the organic facies in the Eromanga basin, in D.I. Gravestock, P.S. Moore, and G.M. Pitt, eds., Contributions to the geology and hydrocarbon potential of the Eromanga basin: Geological Society of Australia Special Publication 12, p. 203-219.

Cook, A.C., and H.I.M. Struckmeyer, 1986, The role of coal as a source rock for oil, in R.C. Glenie, ed., Second southeastern Australia oil exploration symposium: Adelaide, Petroleum Exploration Society of Australia, p. 419-432.

Cooper, B.S., and D.G. Murchison, 1969, Organic geochemistry of coal, in G. Eglinton and M.T.J. Murphy, eds., Organic geochemistry: New York, Springer-Verlag, p. 699-726.Cooper, B.S., and D.G. Murchison, 1971, The petrology and geochemistry of sporinite, in J. Brooks, P.R. Grant, M. Muir, P. Van Gijzel, and G. Shaw, eds., Sporopollenin: New York, Academic Press, p. 545-568.

Copard, Y., J.R. Disnar, and J.F. Becq-Giraudon, 2002, Erroneous maturity assessment given by T max and HI Rock-Eval parameters on highly mature weathered coals: International Journal of Coal Geology, v. 49, p. 57-65.

Copard, Y., J.R. Disnar, J.F. Becq-Giraudon, and F. Laggoun-Defarge, 2004, Erroneous coal maturity assessment caused by low temperature oxidation: International Journal of Coal Geology, v. 58, p. 171-180.

Cope, M.J., 1993, A preliminary study of charcoalified plant fossils from the Middle Jurassic Scalby Formation of North Yorkshire: London, The Palaeontological Association, Special Papers in Palaeontology, v. 49, p. 101-111.Cope, M.J., and W.G. Chaloner, 1980, Fossil charcoal as evidence of past atmospheric composition: Nature, v. 283, p. 647-649.

Cornah, A., J. Vann, and I. Driver, 2013, Comparison of three geostatistical approaches to quantify the impact of drill spacing on resource confidence for a coal seam (with a case example from Moranbah North, Queensland, Australia): International Journal of Coal Geology, v. 112, p. 114-124.

Cornett, M.S., 1993, Coal gasification: Journal of Coal Quality, v. 12, no. 1, p. 14-18.Cornford, C., P. Gardner, and C. Burgess, 1998, Geochemical truths in large data sets. I: Geochemical screening data: Organic Geochemistry, v. 29, p. 519-530.Corrêa da Silva, Z., 1989, The rank evaluation of south Brazillian Gondwana coals on the basis of different chemical and physical parameters: International Journal of Coal Geology, v. 13, p. 21-39.Correa da Silva, Z.C., 2004, Coal facies studies in Brazil: a short review: International Journal of Coal Geology, v. 58, p. 119-124.Correa Da Silva, Z.C., and J. Pereira Neto, 1993, Oxidation effects on macerals of the Candiota coal, Rio Grande Do Sul State, southern Brazil, stocked in piles (abstract): ICCP News, no. 8, p. 13.Correia, M., 1967, Relations possibles entre l'etat de conversation des elements figures de la matiere organique et l'existence de gisements d'hydrocarbures: Revue de l'Institut Francais du Petrole, v. 22, p. 1285-1306.Correia, M., 1969, Contribution a la recherche de zones favorable a la genese du petrole par l'observation microscopique de la matiere organique figuree: Revue de l'Institut Francais du Petrole, v. 24, p. 1417-1454.

Correia, M., and G. Peniguel, 1975, Etude microscopique de la matiere organique - ses applications a l'exploration petroliere: Bull. Centre Rech., Pau - SNPA, v. 9, p. 99-127.Costa, A., D. Flores, I. Suárez-Ruiz, C. Pevida, F. Rubiera, and M.J. Iglesias, 2010, The importance of thermal behavior and petrographic composition for understanding the characteristics of a Portuguese perhydrous Jurassic coal: International Journal of Coal Geology, v. 84, p. 237-247.

Counts, R.A., 1990, Ownership questions can stymie development of coalbed methane: Oil & Gas Journal, v. 88, no. 1, p. 66-70.Courel, L., 1989, Organics versus clastics: conditions necessary for peat (coal) development: International Journal of Coal Geology, v. 12, p. 193-207.Cox, D.O., 1993, Coal-seam water production and disposal, San Juan Basin: Quarterly Review of Methane from Coal Seams Technology, v. 11, p. 26-30.Cox, J.L., 1984, Concern over coal samples: Fuel, v. 63, p. 1030-1031.Craig, J., U. Biffi, R.F. Galimberti, K.A.R. Ghori, J.D. Gorter, N. Hakhoo, D.P. Le Heron, J. Thurow, and M. Vecoli, 2013, The palaeobiology and geochemistry of Precambrian hydrocarbon source rocks: Marine and Petroleum Geology, v. 40, p. 1-47.Cramer, B., 2004, Methane generation from coal during open system pyrolysis investigated by isotope specific, Gaussian distributed reaction kinetics: Organic Geochemistry, v. 35, p. 379-392.Cramer, D., 2008, Stimulation key in unconventional plays: American Oil & Gas Reporter, v. 51, no. 7, p. 101-107.Crane, W.R., 1906, Asphaltic coals: Mines and Minerals, v. 26, p. 252-255.

Crawford, D.L., ed., 1993, Microbial transformations of low rank coals: Boca Raton, CRC Press, 223 p.Crawford, D.L., ed., 1993, Microbial transformations of low rank coals: Boca Raton, CRC Press, 223 p.Crawford, P.M., K. Biglarbigi, E. Knaus, and J. Killen, 2009, Oil shale—2. New approaches overcome past technical issues: Oil & Gas Journal, v. 107.4, p. 44-49.Creaney, S., 1978, Spore fluorescence coloration—a rapid microscopic method of maturation assessment: Geological Survey of Canada, Paper 78-1C, Current Research Part C, p. 101-103.Creaney, S., 1980, Petrographic texture and vitrinite reflectance variation on the Alston Block, north-east England: Proceedings of the Yorkshire Geological Society, v. 42, no. 32, p. 553-580.Creaney, S., 1980, Petrographic texture and vitrinite reflectance variation on the Alston Block, north-east England: Proceedings of the Yorkshire Geological Society, v. 42, p. 553-580.Creaney, S., 1980, The organic petrology of the Upper Cretaceous Boundary Creek Formation, Beaufort-Mackenzie basin: Bulletin of Canadian Petroleum Geology, v. 28, p. 112-129.Creaney, S., D.E. Pearson, and L.G. Marconi, 1980, Anomalous coking properties of the Wolgan seam, NSW, Australia: Fuel, v. 59, p. 438-440.

Copard, Y., J.R. Disnar, and J.F. Becq-Giraudon, 2002, Erroneous maturity assessment given by T max and HI Rock-Eval parameters on highly mature weathered coals: International Journal of Coal Geology, v. 49, p. 57-65.Copard, Y., J.R. Disnar, and J.F. Becq-Giraudon, 2002, Erroneous maturity assessment given by T max and HI Rock-Eval parameters on highly mature weathered coals: International Journal of Coal Geology, v. 49, p. 57-65.

Cope, M.J. 1980, Physical and chemical properties of coalified and charcoalified phytoclasts from some British Mesozoic sediments: an organic geochemical approach to palaeobotany, in A.G. Douglas and J.R. Maxwell, eds., Advances in Organic Geochemistry 1979: New York, Pergamon Press, Physics and Chemistry of the Earth, v. 12, p. 663-677.Cope, M.J., 1980, Physical and chemical properties of coalified and charcoalified phytoclasts from some British Mesozoic sediments: an organic geochemical approach to palaeobotany, in A.G. Douglas and J.R. Maxwell, eds., Advances in Organic Geochemistry 1979: New York, Pergamon Press, p. 663-677.Cope, M.J., 1981, Products of natural burning as a component of the dispersed organic matter of sedimentary rocks, in J. Brooks, ed., Organic maturation studies and fossil fuel exploration: New York, Academic Press, p. 89-109.

Cope, M.J., and W.G. Chaloner, 1985, Wildfire: an interaction of biological and physical processes, in B.H. Tiffney, ed., Geological factors and the evolution of plants: New Haven, Yale University Press, p. 257-277.Cope, M.J., and W.G. Chaloner, 1985, Wildfire: an interaction of biological and physical processes, in B.H. Tiffney, ed., Geological factors and the evolution of plants: New Haven, Yale University Press, p. 257-277.

Cornelius, C.D., 1987, Classification of natural bitumen: a physical and chemical approach, in R.F. Meyer, ed., Exploration for heavy crude oil and natural bitumen: AAPG Studies in Geology 25, p. 165-174.

Correia, M., 1971, Diagenesis of sporopollenin and other comparable organic substances: application to hydrocarbon research, in J. Brooks, P.R. Grant, M. Muir, P. van Gijzel, and G. Shaw, eds., Sporopollenin: New York, Academic Press, p. 569-620.

Couch, G.R., 2002, Coal upgrading to reduce CO2 emissions: International Energy Agency, CCC/67, 72 p.

Crawford, A.L., 1949, Gilsonite and related hydrocarbons of the Uinta basin, Utah, in G.H. Hansen and M.M. Bell, eds., The oil and gas possibilities of Utah: Utah Geological and Mineralogical Survey, p. 235-260.Crawford, A.L., and R.G. Pruitt, 1963, Gilsonite and other bituminous resources of central Uintah County, Utah, in A.L. Crawford, ed., Oil and gas possibilities of Utah, re-evaluated: Utah Geological and Mineralogical Survey, Bulletin 54, p. 215-224.

Creedy, D.P., 1988, Geological controls on the formation and distribution of gas in British coal measure strata: International Journal of Coal Geology, v. 10, p. 1-31.Creedy, D.P., 2002, CBM business in China: World Coal, v. 11, no. 6, p. 65-68.Creelman, R.A., and C.R. Ward, 1996, A scanning electron microscope method for automated, quantitative analysis of mineral matter in coal: International Journal of Coal Geology, v. 30, p. 249-269.Crelling, J.C., 1982, Automated petrographic characterization of coal lithotypes: International Journal of Coal Geology, v. 1, p. 347-359.Crelling, J.C., 1982, Automated petrographic characterization of coal lithotypes: International Journal of Coal Geology, v. 1, p. 347-359.Crelling, J.C., 1983, Current uses of fluorescence microscopy in coal petrology: Journal of Microscopy, v. 132, pt. 3, p. 251-266.Crelling, J.C., 1983, Current uses of fluorescence microscopy in coal petrology: Journal of Microscopy, v. 132, pt. 3, p. 251-266.Crelling, J.C., 1988, Separation and characterization of coal macerals including pseudovitrinite: 1988 Ironmaking Conference Proceedings, p. 351-356.

Crelling, J.C., 1991, Types of vitrinite macerals III: pseudovitrinite: TSOP Newsletter, v. 8, no. 1, p. 14-15.Crelling, J.C., 1994, Coal combustion under conditions of blast furnace injection (abstract): TSOP Abstracts and Program, v. 11, p. 14.

Crelling, J.C., and K.M. Thomas, 1994, Review of some recent research on the combustion properties of coal macerals: Preprints, American Chemical Society, Division of Fuel Chemistry, v. 39, no. 1, p. 13-17.Crelling, J.C., and M.A. Kruge, 1998, Petrographic and chemical properties of carboniferous resinite from the Herrin No. 6, coal seam: International Journal of Coal Geology, v. 37, p. 55-71.Crelling, J.C., and R.J. Gray, 2001, Some industrial applications of organic petrology: TSOP Newsletter, v. 18, no. 2, p. 10-14.

Crelling, J.C., E.J. Hippo, B.A. Woerner, and D.P. West, Jr., 1992, Combustion characteristics of selected whole coals and macerals: Fuel, v. 71, p. 151-158.Crelling, J.C., E.J. Hippo, B.A. Woerner, and E.M. Gillespie, 1990, Reactivity of coal macerals: 1990 Ironmaking Conference Proceedings, p. 211-217.Crelling, J.C., I.J. Glasspool, J.R. Gibbins, and M. Seitz, 2005, Bireflectance imaging of coal and carbon specimens: International Journal of Coal Geology, v. 64, p. 204-216.Crelling, J.C., N.M. Skorupska, and H. Marsh, 1988, Reactivity of coal macerals and lithotypes: Fuel, v. 67, p. 781-785.Crelling, J.C., N.M. Skorupska, and H. Marsh, 1988, Reactivity of coal macerals and lithotypes: Fuel, v. 67, p. 781-785.Crelling, J.C., R.H. Schrader, and L.G. Benedict, 1979, Effects of weathered coal on coking properties and coke quality: Fuel, v. 58, p. 542-546.Crelling, J.C., R.H. Schrader, and L.G. Benedict, 1979, Effects of weathered coal on coking properties and coke quality: Fuel, v. 58, p. 542-546.Crelling, J.C., R.J. Pugmire, H.L.C. Meuzelaar, W.H. McClennen, H. Huai, and J. Karas, 1991, The chemical structure and petrology of resinite from the Hiawatha "B" coal seam: Energy and Fuels, v. 5, p. 688-694.

Cressey, B.A., and G. Cressey, 1988, Preliminary mineralogical investigation of Leicestershire low-rank coal: International Journal of Coal Geology, v. 10, p. 177-191.Crick, I.H., 1992, Petrological and maturation characteristics of organic matter from the middle Proterozoic McArthur basin, Australia: Australian Journal of Earth Sciences, v. 39, p. 501-519.Crick, I.H., C.J. Boreham, A.C. Cook, and T.G. Powell, 1988, Petroleum geology and geochemistry of middle Proterozoic McArthur basin, northern Australia II: assessment of source rock potential: AAPG Bulletin, v. 72, p. 1495-1514.Crisp, P.T., J. Ellis, A.C. Hutton, J. Korth, F.A. Martin, and J.D. Saxby, 1987, Australian oil shales: a compendium of geological and chemical data: CSIRO Institute of Energy and Earth Resources, Division of Fossil Fuels, North Ryde, NSW, Australia, 109 p.Crocker, M., and S. Morton, III, 2010, Development of an algae-based system for CO2 mitigation from coal-fired power plants: University of Kentucky Center for Applied Energy Research, Energeia, v. 21, no. 6, p. 1-4.Croft, G.D., and T.W. Patzek, 2009, Potential for coal-to-liquids conversion in the U.S.–Resource base: Natural Resources Research, v. 18, no. 3.Crosdale, P.J., 1993, Coal maceral ratios as indicators of environment of deposition: do they work for ombrogenous mires? An example from the Miocene of New Zealand: Organic Geochemistry, v. 20, p. 797-809.

Crelling, J.C., 1989, The nature of coal material, in H. Marsh, ed., Introduction to carbon science: Boston, Butterworths, p. 259-284.Crelling, J.C., 1989, The nature of coal material, in H. Marsh, ed., Introduction to carbon science: Boston, Butterworths, p. 259-284.

Crelling, J.C., 1995, The petrology of resinite in American coals, in K.B. Anderson and J.C. Crelling, eds., Amber, resinite, and fossil resins: Washington, D.C., American Chemical Society Symposium Series 617, p. 218-233.Crelling, J.C., 2003, Petrographic atlas of coals, cokes, chars, carbons and graphites: Coal Research Center and Department of Geology, Southern Illinois University at Carbondale, we site at http://mccoy.lib.siu.edu/projects/crelling2/atlas/. Crelling, J.C., 2003, Petrographic atlas of coals, cokes, chars, carbons and graphites: Coal Research Center and Department of Geology, Southern Illinois University at Carbondale, web site at http://mccoy.lib.siu.edu/projects/crelling2/atlas/. Crelling, J.C., 2008, Coal carbonization, in I. Suárez-Ruiz and J.C. Crelling, eds., Applied coal petrology: the role of petrology in coal utilization: New York, Academic Press, p. 173-192.Crelling, J.C., and D.F. Bensley, 1980, Petrology of cutinite-rich coal from the Roaring Creek mine, Parke County, Indiana, in R.L. Langenheim, Jr., and C.J. Mann, eds., Middle and Late Pennsylvanian strata on margin of Illinois basin, Vermilion County, Illinois and Vermillion and Parke Counties, Indiana: SEPM Great Lakes Section, Tenth Annual Field Conference, p. 93-104.Crelling, J.C., and D.F. Bensley, 1984, Characterization of coal macerals by fluorescence microscopy, in R.E. Winans and J.C. Crelling, ed., Chemistry and characterization of coal macerals: American Chemical Society, Symposium Series 252, p. 33-45.Crelling, J.C., and D.F. Bensley, 1984, Characterization of coal macerals by fluorescence microscopy, in R.E. Winans and J.C. Crelling, ed., Chemistry and characterization of coal macerals: American Chemical Society, Symposium Series 252, p. 33-45.Crelling, J.C., and D.F. Bensley, 1995, Recent advances in separating and characterizing single coal macerals, in J.A. Pajares and J.M.D. Tascón, eds., Coal science, v. 1: New York, Elsevier, Coal Science and Technology 24, p. 235-238.Crelling, J.C., and D.F. Bensley, 1995, Recent advances in separating and characterizing single coal macerals, in J.A. Pajares and J.M.D. Tascon, eds., Coal science: New York, Elsevier, Coal Science and Technology 24, v. 1, p. 235-238.

Crelling, J.C., and R.R. Dutcher, 1980, Fluorescent macerals in Colorado coking coals, in L.M. Carter, ed., Proceedings of the fourth symposium on the geology of Rocky Mountain coal—1980: Colorado Geological Survey, Resource Series 10, p. 58-61.

Crelling, J.C., R.R. Dutcher, and R.V. Lange, 1982, Petrographic and fluorescence properties of resinite macerals from western U.S. coals, in K.D. Gurgel, ed., Proceedings of the fifth symposium on the geology of Rocky Mountain coal—1982: Utah Geological and Mineral Survey, Bulletin 118, p. 187-191.

Crosdale, P.J., 1993, Coal maceral ratios as indicators of environment of deposition: do they work for ombrogenous mires? An example from the Miocene of New Zealand: Organic Geochemistry, v. 20, p. 797-809. (origin of bituminite, p. 805)Crosdale, P.J., 1995, Lithotype sequences in the early Miocene Maryville coal measures, New Zealand: International Journal of Coal Geology, v. 28, p. 37-50.Crosdale, P.J., 2002, Dredging up degradinite: ICCP News, No. 26, p. 18-19.Crosdale, P.J., 2004, Coal facies studies in Australia: International Journal of Coal Geology, v. 58, p. 125-130.Crosdale, P.J., and A.C. Cook, 2008, Discussion: Anderson, K.B., Crelling, J.C., Kenig, F., Huggett, W.W., 2007. An unusual non-fluorescing algal kerogen from the Canadian Arctic: International Journal of Coal Geology, v. 73, p. 388-390.

Crosdale, P.J., T.A. Moore, and T.E. Mares, 2008, Influence of moisture content and temperature on methane adsorption isotherm analysis for coals from a low-rank, biogenically-sourced gas reservoir: International Journal of Coal Geology, v. 76, p. 166-174.Cross, A.T., and G.D. Wood, 1976, Palynology and petrography of some solid bitumens of the Uinta basin, Utah: Brigham Young University Geology Studies, v. 22, p. 157-173.

Crovelli, R.A., 2003, Probabilistic assessment methodology for continuous-type petroleum accumulations: International Journal of Coal Geology, v. 56, p. 45-48.Crowley, S., R. Reynolds, R. Finkelman, M. Brownfield, C. Palmer, C. Eble, and H. Belkin, 1996, Characterization of Cr, Ni, and Co in fly ash from a coal-burning power plant in Kentucky (abstract): TSOP Abstracts and Program, v. 13, p. 29-31.Crowley, S.S., L.F. Ruppert, H.E. Belkin, R.W. Stanton, and T.A. Moore, 1993, Factors affecting the geochemistry of a thick, subbituminous coal bed in the Powder River basin: volcanic, detrital, and peat-forming processes: Organic Geochemistry, v. 20, p. 843-853.Crowley, S.S., R.W. Stanton, and L.F. Ruppert, 1993, Air toxics in coal: the distribution of twelve trace elements in a thick, subbituminous coal bed and impact on mining applications: Journal of Coal Quality, v. 12, no. 4, p. 141-146.Crowley, S.S., R.W. Stanton, and L.F. Ruppert, 1993, Air toxics in coal: the distribution of twelve trace elements in a thick, subbituminous coal bed and impact on mining applications: Journal of Coal Quality, v. 12, p. 141-146.

Cui, X., and R.M. Bustin, 2005, Volumetric strain associated with methane desorption and its impact on coalbed gas production from deep coal seams: AAPG Bulletin, v. 89, p. 1181-1202.Cui, X., R.M. Bustin, and G. Dipple, 2004, Differential transport of CO2 and CH4 in coalbed aquifers: implications for coalbed gas distribution and composition: AAPG Bulletin, v. 88, p. 1149-1161.Cui, X., R.M. Bustin, and G. Dipple, 2004, Selective transport of CO2, CH4, and N2 in coals: insights from modeling of experimental gas adsorption data: Fuel, v. 83, p. 293-303.Curiale, J., R. Lin, and E. Lumadyo, 2002, Coal-sourced oils surrounding the Salayar Basin, Indonesia (abstract): TSOP Annual Meeting, abstract A3.1.3.Curiale, J.A., 1983, Petroleum occurrences and source-rock potential of the Ouachita Mountains, southeastern Oklahoma: Oklahoma Geological Survey, Bulletin 135, 65 p.Curiale, J.A., 1986, Origin of solid bitumens, with emphasis on biological marker results: Organic Geochemistry, v. 10, p. 559-580.

Curiale, J.A., and W.E. Harrison, 1981, Correlation of oil and asphaltite in Ouachita Mountain region of Oklahoma: AAPG Bulletin, v. 65, p. 2426-2432.Curiale, J.A., P. Kyi, I.D. Collins, A. Din, K. Nyein, M. Nyunt, and C.J. Stuart, 1994, The central Myanmar (Burma) oil family - composition and implications for source: Organic Geochemistry, v. 22, p. 237-255.Curiale, J.A., W.E. Harrison, and G. Smith, 1983, Sterane distribution of solid bitumen pyrolyzates. Changes with biodegradation of crude oil in the Ouachita Mountains, Oklahoma: Geochimica et Cosmochimica Acta, v. 47, p. 517-523.Curl, S.J., 1978, Methane prediction in coal mines: IEA Coal Research, Report no. ICTIS/TR 4, 79 p.Curry, D.J., and K.M. Bohacs, 2002, The influence of sequence stratigraphic position on the oil generation potential of coals (abstract): TSOP Annual Meeting, abstract A3.1.1.

Cutruneo, C.M.N.L., M.L.S. Oliveira, C.R. Ward, J.C. Hower, I.A.S. de Brum, C.H. Sampaio, R.M. Kautzmann, S.R. Taffarel, E.C. Teixeira, and L.F.O. Silva, 2014, A mineralogical and geochemical study of three Brazilian coal cleaning rejects: Demonstration of electron beam applications: International Journal of Coal Geology, v. 130, p. 33-52.Cutruneo, C.M.N.L., M.L.S. Oliveira, C.R. Ward, J.C. Hower, I.A.S. de Brum, C.H. Sampaio, R.M. Kautzmann, S.R. Taffarel, E.C. Teixeira, and L.F.O. Silva, 2014, A mineralogical and geochemical study of three Brazilian coal cleaning rejects: Demonstration of electron beam applications: International Journal of Coal Geology, v. 130, p. 33-52.Czechoski, F., B.R.T. Simoneit, M. Sachanbinski, J. Chojcan, and S. Wolowiec, 1996, Physicochemical structural characterization of ambers from deposits in Poland: Applied Geochemistry, v. 11, p. 811-834.Czerw, K., 2011, Methane and carbon dioxide sorption/desorption on bituminous coal—Experiments on cubicoid samples cut from the primal coal lump: International Journal of Coal Geology, v. 85, p. 72-77.Czerw, K., 2011, Methane and carbon dioxide sorption/desorption on bituminous coal—Experiments on cubicoid samples cut from the primal coal lump: International Journal of Coal Geology, v. 85, p. 72-77.Czimczik, C.I., C.M. Preston, M.W.I. Schmidt, R.A. Werner, and E.-D. Schulze, 2002, Effects of charring on mass, organic carbon, and stable carbon isotope composition of wood: Organic Geochemistry, v. 33, p. 1207-1223.Czimczik, C.I., C.M. Preston, M.W.I. Schmidt, R.A. Werner, and E.-D. Schulze, 2002, Effects of charring on mass, organic carbon, and stable isotope composition of wood: Organic Geochemistry, v. 33, p. 1207-1223.D’Amico, J.S., 2000, Processing key to CBM economics: American Oil & Gas Reporter, v. 43, no. 8, p. 118-124.

Crosdale, P.J., B.B. Beamish, and M. Valix, 1998, Coalbed methane sorption related to coal composition, in R.M. Flores, ed., Coalbed methane: from coal-mine outbursts to a gas resource: International Journal of Coal Geology, v. 35, p. 147-158.

Cross, T.A., 1988, Controls on coal distribution in transgressive-regressive cycles, Upper Cretaceous, Western Interior, U.S.A., in C.K. Wilgus, B.S. Hastings, C.G. st. C. Kendall, H.W. Posamentier, C.A. Ross, and J.C. van Wagoner, eds., Sea-level changes: an integrated approach: SEPM Special Publication 42, p. 371-380.

Cudmore, J.F., 1984, Coal utilization, in C.R. Ward, ed., Coal geology and coal technology: Boston, Blackwell Scientific Publications, p. 113-150.

Curiale, J.A., 1987, Distribution and occurrence of metals in heavy crude oils and solid bitumens — implications for petroleum exploration, in R.F. Meyer, ed., Exploration for heavy crude oil and natural bitumen: AAPG Studies in Geology 25, p. 207-219.Curiale, J.A., 1988, Biological markers in grahamites and pyrobitumens, in T.F. Yen and J.M. Moldowan, eds., Geochemical biomarkers: New York, Harwood Academic Publishers, p. 1-24.Curiale, J.A., 1993, Occurrence and significance of metals in solid bitumens: an organic geochemical approach, in J. Parnell, H. Kucha, and P. Landais, eds., Bitumens in ore deposits: New York, Springer-Verlag, p. 461-474.Curiale, J.A., and R. Lin, 1991, Tertiary deltaic and lacustrine organic facies: comparison of biomarker and kerogen distributions, in P.K. Mukhopadhyay, M.G. Fowler, and W.G. Dow, eds., Selected papers from the symposium on coal and terrestrial organic matter as a source rock for petroleum: Organic Geochemistry, v. 17, p. 785-803.

Curry, D.J., J.K. Emmett, and J.W. Hunt, 1994, Geochemistry of aliphatic-rich coals in the Cooper basin, Australia and Taranaki basin, New Zealand: implications for the occurrence of potentially oil-generative coals, in A.C. Scott and A.J. Fleet, eds., Coal and coal-bearing strata as oil-prone source rocks?: London, The Geological Society Special Publication 77, p. 149-181.

Dabbous, M.K., A.A. Reznik, J.J. Taber, and P.F.Fulton, 1992, The permeability of coal to gas and water, in Coalbed methane: Society of Petroleum Engineers, Reprint Series 35, p. 46-55.Dabbous, M.K., A.A. Reznik, J.J. Taber, and P.F.Fulton, 1992, The permeability of coal to gas and water, in Coalbed methane: Society of Petroleum Engineers, Reprint Series 35, p. 46-55.

Dahl, B., J. Bojesen-Koefoed, A. Holm, H. Justwan, E. Rasmussen, and E. Thomsen, 2004, A new approach to interpreting Rock-Eval S2 and TOC data for kerogen quality assessment: Organic Geochemistry, v. 35, p. 1461-1477.Dai, J., C. Zou, J. Li, Y. Ni, G. Hu, X. Zhang, Q. Liu, C. Yang, and A. Hu, 2009, Carbon isotopes of Middle-Lower Jurassic coal-derived alkane gases from the major basins of northwestern China: International Journal of Coal Geology, v. 80, p. 124-134.Dai, J., D. Gong, Y. Ni, S. Huang, and W. Wu, 2014, Stable carbon isotopes of coal-derived gases sourced from the Mesozoic coal measures in China: Organic Geochemistry, v. 74, p. 123-142.Dai, S., C.-L. Chou, M. Yue, K. Luo, and D. Ren, 2005, Mineralogy and geochemistry of a Late Permian coal in the Dafang coalfield, Guizhou, China: influence from siliceous and iron-rich calcic hydrothermal fluids: International Journal of Coal Geology, v. 61, p. 241-258.Dai, S., D. Li, C.-L. Chou, L. Zhao, Y. Zhang, D. Ren, Y. Ma, and Y. Sun, 2008, Mineralogy and geochemistry of boehmite-rich coals: New insights from the Haerwusu surface mine, Jungar Coalfield, Inner Mongolia, China: International Journal of Coal Geology, v. 74, p. 185-202.Dai, S., D. Li, D. Ren, Y. Tang, L. Shao, and H. Song, 2004, Geochemistry of the late Permian No. 30 coal seam, Zhijin Coalfield of southwest China: influence of a siliceous low-temperature hydrothermal fluid: Applied Geochemistry, v. 19, p. 1315-1330.Dai, S., D. Ren, C.-L. Chou, R.B. Finkelman, V.V. Seredin, and Y. Zhou, 2012, Geochemistry of trace elements in Chinese coals: A review of abundances, genetic types, impacts on human health, and industrial utilization: International Journal of Coal Geology, v. 94, p. 3-21.Dai, S., D. Ren, Y. Tang, L. Shao, and S. Li, 2002, Distribution, isotopic variation and origin of sulfur in coals in the Wuda coalfield, Inner Mongolia, China: International Journal of Coal Geology, v. 51, p. 237-250.Dai, S., D. Ren, Y. Tang, M. Yue, and L. Hao, 2005, Concentration and distribution of elements in Late Permian coals from western Guizhou Province, China: International Journal of Coal Geology, v. 61, p. 119-137.Dai, S., J. Zou, Y. Jiang, C.R. Ward, X. Wang, T. Li, W. Xue, S. Liu, H. Tian, X. Sun, and D. Zhou, 2012, Mineralogical and geochemical compositions of the Pennsylvanian coal in the Adaohai mine, Daqingshan Coalfield, Inner Mongolia, China: Modes of occurrence and origin of diaspora, gorceixite, and ammonian illite: International Journal of Coal Geology, v. 94, p. 250-270.Dai, S., J. Zou, Y. Jiang, C.R. Ward, X. Wang, T. Li, W. Xue, S. Liu, H. Tian, X. Sun, and D. Zhou, 2012, Mineralogical and geochemical compositions of the Pennsylvanian coal in the Adaohai mine, Daqingshan Coalfield, Inner Mongolia, China: Modes of occurrence and origin of diaspora, gorceixite, and ammonian illite: International Journal of Coal Geology, v. 94, p. 250-270.Dai, S., L. Tian, C.-L. Chou, Y. Zhou, M. Zhang, L. Zhao, J. Wang, Z. Yang, H. Cao, and D. Ren, 2008, Mineralogical and compositional characteristics of Late Permian coals from an area of high lung cancer rate in Xuan Wei, Yunnan, China: Occurrence and origin of quartz and chamosite: International Journal of Coal Geology, v. 76, p. 318-327.Dai, S., L. Zhao, S. Peng, C.-L. Chou, X. Wang, Y. Zhang, D. Li, and Y. Sun, 2010, Abundances and distribution of minerals and elements in high-alumina coal fly ash from the Jungar power plant, Inner Mongolia, China: International Journal of Coal Geology, v. 81, p. 320-332.Dai, S., R. Zeng, and Y. Sun, 2006, Enrichment of arsenic, antimony, mercury, and thallium in a Late Permian anthracite from Xingren, Guizhou, southwest China: International Journal of Coal Geology, v. 66, p. 217-226.Dai, S., T. Li, V.V. Seredin, C.R. Ward, J.C. Hower, Y. Zhou, M. Zhang, X. Song, W. Song, and C. Zhao, 2014, Origin of minerals and elements in the Late Permian coals, tonsteins, and host rocks of the Xinde Mine, Xuanwei, eastern Yunnan, China: International Journal of Coal Geology, v. 121, p. 53-78.Dai, S., V.V. Seredin, C.R. Ward, J. Jiang, J.C. Hower, X. Song, Y. Jiang, X. Wang, T. Gornostaeva, X. Li, H. Liu, L. Zhao, and C. Zhao, 2014, Composition and modes of occurrence of minerals and elements in coal combustion products derived from high-Ge coals: International Journal of Coal Geology, v. 121, p. 79-97. (Germanium)Dai, S., V.V. Seredin, C.R. Ward, J. Jiang, J.C. Hower, X. Song, Y. Jiang, X. Wang, T. Gornostaeva, X. Li, H. Liu, L. Zhao, and C. Zhao, 2014, Composition and modes of occurrence of minerals and elements in coal combustion products derived from high-Ge coals: International Journal of Coal Geology, v. 121, p. 79-97.Dai, S., V.V. Seredin, C.R. Ward, J. Jiang, J.C. Hower, X. Song, Y. Jiang, X. Wang, T. Gornostaeva, X. Li, H. Liu, L. Zhao, and C. Zhao, 2014, Composition and modes of occurrence of minerals and elements in coal combustion products derived from high-Ge coals: International Journal of Coal Geology, v. 121, p. 79-97.Dai, S., W. Li, Y. Tang, Y. Zhang, and P. Feng, 2007, The sources, pathway, and preventive measures for fluorosis in Zhijin County, Guizhou, China: Applied Geochemistry, v. 22, p. 1017-1024.Dai, S., W. Zhang, C.R. Ward, V.V. Seredin, J.C. Hower, X. Li, W. Song, X. Wang, H. Kang, L. Zheng, P. Wang, and D. Zhou, 2013, Mineralogical and geochemical anomalies of late Permian coals from the Fusui coalfield, Guangxi Province, southern China: Influences of terrigenous materials and hydrothermal fluids: International Journal of Coal Geology, v. 105, p. 60-84.Dai, S., W. Zhang, V.V. Seredin, C.R. Ward, J.C. Hower, W. Song, X. Wang, X. Li, L. Zhao, H. Kang, L. Zheng, P. Wang, and D. Zhou, 2013, Factors controlling geochemical and mineralogical compositions of coals preserved within marine carbonate successions: A case study from the Heshan coalfield, southern China: International Journal of Coal Geology, v. 109-110, p. 77-100.Dai, S., X. Hou, D. Ren, and Y. Tang, 2003, Surface analysis of pyrite in the No. 9 coal seam, Wuda coalfield, Inner Mongolia, China, using high-resolution time-of-flight secondary ion mass-spectrometry: International Journal of Coal Geology, v. 55, p. 139-150.Dai, S., X. Wang, V.V. Seredin, J.C. Hower, C.R. Ward, J.M.K. O’Keefe, W. Huang, T. Li, X. Li, H. Liu, W. Xue, and L. Zhao, 2012, Petrology, mineralogy, and geochemistry of the Ge-rich coal from the Wulantuga Ge ore deposit, Inner Mongolia, China: New data and genetic implications: International Journal of Coal Geology, v. 90-91, p. 72-99. (Germanium) [erratum in International Journal of Coal Geology, v. 105, p. 141]Dai, S., X. Wang, W. Chen, D. Li, C-L. Chou, Y. Zhou, C. Zhu, H. Li, X. Zhu, Y. Xing, W. Zhang, and J. Zou, 2010, A high-pyrite semianthracite of Late Permian age in the Songzao coalfield, southwestern China: mineralogical and geochemical relations with underlying mafic tuffs: International Journal of Coal Geology, v. 83, p. 430-445.Dai, S., Y. Jiang, C.R. Ward, L. Gu, V.V. Seredin, H. Liu, D. Zhou, X. Wang, Y. Sun, J. Zou, and D. Ren, 2012, Mineralogical and geochemical compositions of the coal in the Guanbanwusu mine, Inner Mongolia, China: Further evidence for the existence of an Al (Ga and REE) ore deposit in the Jungar coalfield: International Journal of Coal Geology, v. 98, p. 10-40.Dai, S., Y. Jiang, C.R. Ward, L. Gu, V.V. Seredin, H. Liu, D. Zhou, X. Wang, Y. Sun, J. Zou, and D. Ren, 2012, Mineralogical and geochemical compositions of the coal in the Guanbanwusu mine, Inner Mongolia, China: Further evidence for the existence of an Al (Ga and REE) ore deposit in the Jungar coalfield: International Journal of Coal Geology, v. 98, p. 10-40.Dai, S., Y. Luo, V.V. Seredin, C.R. Ward, J.C. Hower, L. Zhao, S. Liu, C. Zhao, H. Tian, and J. Zou, 2014, Revisiting the late Permian coal from the Huayingshan, Sichuan, southwestern China: Enrichment and occurrence modes of minerals and trace elements: International Journal of Coal Geology, v. 122, p. 110-128.Dai, S., Y. Luo, V.V. Seredin, C.R. Ward, J.C. Hower, L. Zhao, S. Liu, C. Zhao, H. Tian, and J. Zou, 2014, Revisiting the late Permian coal from the Huayingshan, Sichuan, southwestern China: Enrichment and occurrence modes of minerals and trace elements: International Journal of Coal Geology, v. 122, p. 110-128.Dai, S., Y. Zhou, M. Zhang, X. Wang, J. Wang, X. Song, Y. Jiang, Y. Luo, Z. Song, Z> Yang, and D. Ren, 2010, A new type of Nb (Ta) – Zr (HF) – REE – Ga polymetallic deposit in the late Permian coal-bearing strata, eastern Yunnan, southwestern China: Possible economic significance and genetic implications: International Journal of Coal Geology, v. 83, p. 55-63.Dalla Torre, M., R. Ferreiro Mählmann, and W.G. Ernst, 1997, Experimental study on the pressure dependence of vitrinite maturation: Geochimica et Cosmochimica Acta, v. 61, p. 2921-2928.Dalla Torre, M., R. Ferreiro Mählmann, and W.G. Ernst, 1997, Experimental study on the pressure dependence of vitrinite maturation: Geochimica et Cosmochimica Acta, v. 61, p. 2921-2928.Dallbauman, L., 2004, GTI research on carbon dioxide sequestration: GasTIPS, v. 10, no. 2, p. 31-33.Dallegge, T.A., and C.E. Barker, 2002, Implications to conventional gas reserve growth of coalbed methane desorption analyses from the Beaver Creek and Kenai gas fields, Kenai Peninsula, Alaska (abstract): AAPG Bulletin, v. 86, p. 1140-1141.Daly, D.J., and G. Mesing, 1993, Gas industry-related produced-water demographics: Quarterly Review of Methane from Coal Seams Technology, v. 11, no. 2, p. 3-5.Daly, D.J., and G. Mesing, 1993, Gas industry-related produced-water demographics: Quarterly Review of Methane from Coal Seams Technology, v. 11, no. 2, p. 3-5.

Damen, K., A. Faaij, F. Van Bergen, J. Gale, and E. Lysen, 2005, Identification of early opportunities for CO2 sequestration—worldwide screening for CO2-EOR and CO2-ECBM projects: Energy, v. 30, p. 1931-1952.Dance, T., 2013, Assessment and geological characterization of the CO2CRC Otway Project CO2 storage demonstration site: From prefeasibility to injection: Marine and Petroleum Geology, v. 46, p. 251-269.

Danell, R.E., Å. Källstrand, J. Nunn, and B. Heed, 2001, Reduction of methane emissions from underground coal mining: demonstration of abatement and utilisation in mine ventilation exhaust air: Proceedings, International Coalbed Methane Symposium, p. 87-99.

Damberger, H.H., R.D. Harvey, R.R. Ruch, and J. Thomas, 1984, Coal characterization, in B.R. Cooper, and W.A. Ellingson, eds., The science and technology of coal utilization: New York, Plenum Press, p. 7-45.Damberger, H.H., R.D. Harvey, R.R. Ruch, and J. Thomas, Jr., 1984, Coal characterization, in B.R. Cooper and W.A. Ellingson, eds., The science and technology of coal and coal utilization: New York, Plenum Press, p. 7-45.

Dancey, L.A., Y.V. Hardy, and S.A.J. Pocock, 1982, Sample processing for acid insoluble particulate organic matter studies, in F.L. Staplin and others, How to assess maturation and paleotemperatures: SEPM Short Course Notes 7, p. 90-101.

Danell, R.E., Å. Källstrand, J. Nunn, and B. Heed, 2001, Reduction of methane emissions from underground coal mining: demonstration of abatement and utilisation in mine ventilation exhaust air: Tuscaloosa, Alabama, Proceedings, International Coalbed Methane Symposium, Paper 152, p. 87-99.Daniels, E.J., and S.P. Altaner, 1993, Inorganic nitrogen in anthracite from eastern Pennsylvania, USA: International Journal of Coal Geology, v. 22, p. 21-35.Daniels, E.J., and S.P. Altaner, 1993, Inorganic nitrogen in anthracite from eastern Pennsylvania, USA: International Journal of Coal Geology, v. 22, p. 21-35.

Dapples, E.C., 1942, Physical constitution of coal as related to coal description and classification: Journal of Geology, v. 50, p. 437-450.Dapples, E.C., and M.E. Hopkins, eds., 1969, Environments of coal deposition: Geological Society of America Special Paper 114, 204 p.Darbonne, N., 2006, Domestic gas supply: CBM review: Oil and Gas Investor, v. 26, no. 6, p. 65-68.

Darragh, A., and F. Goodarzi, 1985, Canadian coals—their distribution and potential: Journal of Coal Quality, v. 5, p. 35-39.Darton, N.H., 1915, Occurrence of explosive gases in coal mines: U.S. Bureau of Mines Bulletin 72, 248 p.

Dashtgard, S.E., M.B.E. Buschkuehle, B. Fairgrieve, and H. Berhane, 2008, Geological characterization and potential carbon dioxide (CO2) enhanced oil recovery in the Cardium Formation, central Pembina Field, Alberta: Bulletin of Canadian Petroleum Geology, v. 56, p. 147-164.

David, P., and W.J.J. Fermont, 1993, Application of colour image analysis in coal petrology: Organic Geochemistry, v. 20, p. 747-758.Davidson, R., 1993, Organic sulfur in coal: IEA Coal Research, IEACR/60, 79 p.

Davidson, R.M., 1990, Natural oxidation of coal: IEA Coal Research, publication 29, 76 p.Davidson, R.M., 1991, Natural oxidation of coal: University of Kentucky Center for Applied Energy Research, Energeia, v. 2, no. 2, p. 1-4.Davidson, R.M., 1994, Quantifying organic sulfur in coal: a review: Fuel, v. 73, p. 988-.Davidson, R.M., 1996, Chlorine and other halogens in coal: IEA Coal Research Perspectives, IEAPER/28, 46 p.Davidson, R.M., 2000, How coal properties influence emissions: International Energy Agency, CCC/28, 56 p.Davidson, R.M., 2000, Modes of occurrence of trace elements in coal: IEA Coal Research, 36 p.Davidson, R.M., and L.B. Clarke, 1996, Trace elements in coal: IEA Coal Research Perspectives, IEAPER/21, 60 p.Davidson, R.M., L.L. Sloss, and L.B. Clarke, 1995, Coalbed methane extraction: London, IEA Coal Research, IEACR/76, 67 p.

Davies, J.R., A. McNestry, and R.A. Waters, 1991, Palaeoenvironments and palynofacies of a pulsed transgression: the Late Devonian and early Dinantian (Lower Carboniferous) rocks of southeast Wales: Geological Magazine, v. 128, p. 355-380.Davies, R., C. Diessel, J. Howell, S. Flint, and R. Boyd, 2005, Vertical and lateral variation in the petrography of the Upper Cretaceous Sunnyside coal of eastern Utah, USA—implications for the recognition of high-resolution accommodation changes in paralic coal seams: International Journal of Coal Geology, v. 61, p. 13-33.

Davis, A., 1978, Compromise in coal seam description: ASTM STP 661, p. 33-40.

Davis, A., 1992, Coal under the microscope—deciphering the influence of depositional environment: University of Kentucky, Center for Applied Energy Research, Energeia, v. 3, no. 6, p. 1,2,4.Davis, A., 2000, Petrographic determination of the composition of binary coal blends: International Journal of Coal Geology, v. 44, p. 325-338.Davis, A., and F.J. Vastola, 1977, Developments in automated reflectance microscopy of coal: Journal of Microscopy, v. 109, pt. 1, p. 3-12.Davis, A., D.S. Hoover, L.D. Wakeley, and G.D. Mitchell, 1983, The microscopy of mesophase formation and of anisotropic cokes produced from solvent-refined coals: Journal of Microscopy, v. 132, pt. 3, p. 315-331.Davis, A., G.D. Mitchell, F.J. Derbyshire, R.F. Rathbone, and R. Lin, 1991, Optical properties of coals and liquefaction residues as indicators of reactivity: Fuel, v. 70, p. 352-360.Davis, A., K.W. Kuehn, D.H. Maylotte, and R.L. St. Peters, 1983, Mapping of polished coal surfaces by automated reflectance microscopy: Journal of Microscopy, v. 132, pt. 3, p. 297-302.Davis, A., R.F. Rathbone, R. Lin, and J.C. Quick, 1990, Observations concerning the nature of maceral fluorescence alteration with time: Organic Geochemistry, v. 16, p. 897-906.

Daniels, E.J., J.L. Aronson, S.P. Altaner, and N. Clauer, 1994, Late Permian age of NH4-bearing illite in anthracite from eastern Pennsylvania: temporal limits on coalification in the central Appalachians: Geological Society of America Bulletin, v. 106, p. 760-766.

Darby, J.D., and G.F. Hart, 1994, Organic sedimentation in a carbonate region, in A. Traverse, ed., Sedimentation of organic particles: Cambridge University Press, p. 177-197.

Das, B.M., D.J. Nikols, Z.U. Das, and V.J. Hucka, 1991, Factors affecting rate and total volume of methane desorption from coalbeds, in S.D. Schwochow, D.K. Murray, and M.F. Fahy, eds., Coalbed methane of western North America: Denver, Rocky Mountain Association of Geologists, p. 69-76.

Datta, R.K., K.K. Sen, R.N. Das, K. Mondal, and G. Mukherjee, 2001, Coalbed methane prospect in Raniganj coalfield — a prognosis, in Proceedings of national seminar on recent advances in geology of coal and lignite basins of India: Geological Survey of India, Special Publication 54, p. 287-294.

Davidson, R.M., 1982, Molecular structure of coal, in M.L. Gorbaty, and others, eds., Coal science, v. 1: New York, Academic Press, p. 84-160.

Davies, E.H., and M.P. Avery, 1984, A system for vitrinite reflectance analysis on dispersed organic matter for offshore eastern Canada, in Current research, Part A: Geological Survey of Canada Paper 84-1A, p. 367-372.

Davis, A., 1978, Compromise in coal seam description, in R.R. Dutcher, ed., Field description of coal: Philadelphia, PA, American Society for Testing and Materials, Special Technical Publication 661, p. 33-40.

Davis, A., 1978, The reflectance of coal, in C. Carr, Jr., ed., Analytical methods for coal and coal products, v. 1: Academic Press, p. 27-81. (coking, p. 69-78)Davis, A., 1978, The reflectance of coal, in C. Karr, Jr., ed., Analytical methods for coal and coal products, v. 1: New York, Academic Press, p. 27-81.Davis, A., 1978, The reflectance of coal, in C. Karr, Jr., ed., Analytical methods for coal and coal products, v. 1: New York, Academic Press, p. 27-81.Davis, A., 1984, Coal petrology and petrographic analysis, in C.R. Ward, ed., Coal geology and coal technology: Blackwell Scientific Publications, p. 74-112.Davis, A., 1984, Coal petrology and petrographic analysis, in C.R. Ward, ed., Coal geology and coal technology: Palo Alto, Blackwell Scientific Publications, p. 74-112.

Davis, A., R.F. Rathbone, R. Lin, and J.C. Quick, 1990, Observations concerning the nature of maceral fluorescence alteration with time: Organic Geochemistry, v. 16, p. 897-906.Davis, A., S.J. Russell, S.M. Rimmer, and J.D. Yeakel, 1984, Some genetic implications of silica and aluminosilicates in peat and coal: International Journal of Coal Geology, v. 3, p. 293-314.Davis, A., W. Spackman, and P.H. Given, 1976, The influence of the properties of coals on their conversion into clean fuels: Energy Sources, v. 3, no. 1, p. 55-81.Davis, J.B., and J.P. Stanley, 1982, Catalytic effect of smectite clays in hydrocarbon generation revealed by pyrolysis-gas chromatography: Journal of Analytical and Applied Pyrolysis, v. 4, p. 227-240.Davis, R.C., S.W. Noon, and J. Harrington, 2007, The petroleum potential of Tertiary coals from western Indonesia: Relationship to mire type and sequence stratigraphic setting: International Journal of Coal Geology, v. 70, p. 35-52.Davis, R.C., S.W. Noon, and J. Harrington, 2007, The petroleum potential of Tertiary coals from western Indonesia: Relationship to mire type and sequence stratigraphic setting: International Journal of Coal Geology, v. 70, p. 35-52.Davis, R.F., 1981, Evaluation and selection of coals for metallurgical coke: Society of Mining Engineers of AIME, Transactions, v. 270, p. 407-409.Davis, T.L., R.D. Benson, C. Ansorger, and S.L. Roche, 2007, 4-D, 9-C delineates key CBM variables: American Oil & Gas Reporter, v. 50, no. 12, p. 97-101.Dawson, F.M., 1995, Coalbed methane: a comparison between Canada and the United States: Geological Survey of Canada, Bulletin 489, 60 p.

Dawson, F.M., D.L. Marchioni, T.C. Anderson, and W.J. McDougall, 2000, An assessment of coalbed methane exploration projects in Canada: Geological Survey of Canada, Bulletin 549, 218 p.Dawson, F.M., D.L. Marchioni, T.C. Anderson, and W.J. McDougall, 2004, An assessment of coalbed methane exploration projects in Canada: Geological Survey of Canada, Bulletin 549, CD-ROM.Dawson, G.K.W., and J.S. Esterle, 2010, Controls on coal cleat spacing: International Journal of Coal Geology, v. 82, p. 213-218.Dawson, G.K.W., S.D. Golding, J.S. Esterle, and P. Massarotto, 2012, Occurrence of minerals within fractures and matrix of selected Bowen and Ruhr basin coals: International Journal of Coal Geology, v. 94, p. 150-166.Dawson, M., and W. Kalkreuth, 1994, Coal rank and coalbed methane potential of Cretaceous/Tertiary coals in the Canadian Rocky Mountain foothills and adjacent foreland: 1. Hinton and Grande Cache areas, Alberta: Bulletin of Canadian Petroleum Geology, v. 42, p. 544-561.Day, J.C., R.H. Jones, and C.B. Belcher, 1979, Evaluation of coals for the metallurgical and power industries: BHP Technical Bulletin, v. 23, no. 2, p. 11-18.Day, S., R. Fry, and R. Sakurovs, 2008, Swelling of Australian coals in supercritical CO2: International Journal of Coal Geology, v. 74, p. 41-52.Day, S., R. Fry, and R. Sakurovs, 2011, Swelling of moist coal in carbon dioxide and methane: International Journal of Coal Geology, v. 86, p. 197-203.Day, S., R. Fry, and R. Sakurovs, 2011, Swelling of moist coal in carbon dioxide and methane: International Journal of Coal Geology, v. 86, p. 197-203.Day, S., R. Fry, and R. Sakurovs, 2012, Swelling of coal in carbon dioxide, methane and their mixtures: International Journal of Coal Geology, v. 93, p. 40-48.Day, S., R. Fry, and R. Sakurovs, 2012, Swelling of coal in carbon dioxide, methane and their mixtures: International Journal of Coal Geology, v. 93, p. 40-48.Day, S., R. Sakurovs, and S. Weir, 2008, Supercritical gas sorption on moist coals: International Journal of Coal Geology, v. 74, p. 203-214.Day, S., R. Sakurovs, and S. Weir, 2008, Supercritical gas sorption on moist coals: International Journal of Coal Geology, v. 74, p. 203-214.Daybell, G.N., and W.J.S. Pringle, 1958, The mode of occurrence of chlorine in coal: Fuel, v. 37, p. 283-292.De Bruin, R.H., R.M. Lyman, and N.R. Jones, 2003, Coalbed methane update: Wyoming Geo-notes, no. 78, p. 23-24.De Bruin, R.H., R.M. Lyman, and N.R. Jones, 2004, Coalbed methane update: Wyoming Geo-notes, no. 80, p. 21-22.De Bruin, R.H., R.M. Lyman, L.L. Hallberg, and N.R. Jones, 2004, Coalbed methane activity in the eastern Powder River Basin, Campbell and Converse Counties, Wyoming: Wyoming Geological Survey, Map Series 56.De Bruin, R.H., R.M. Lyman, L.L. Hallberg, M.M. Harrison, and N.R. Jones, 2004, Coalbed methane activity in the Powder River Basin, Campbell, Converse, Johnson, Natrona, and Sheridan Counties, Wyoming: Wyoming Geological Survey, Map Series 58.De Bruin, R.H., R.M. Lyman, L.L. Hallberg, M.M. Harrison, and N.R. Jones, 2004, Coalbed methane activity in the western Powder River Basin, Campbell, Converse, Johnson, Natrona, and Sheridan Counties, Wyoming: Wyoming Geological Survey, Map Series 57.De Bruin, R.H., R.M. Lyman, R.W. Jones, and L.W. Cook, 2001, Coalbed methane in Wyoming: Wyoming State Geological Survey, Information Pamphlet 7 (revised).De Caritat, P., A. Hortle, M. Raistrick, C. Stalvies, and C. Jenkins, 2013, Monitoring groundwater flow and chemical and isotopic composition at a demonstration site for carbon dioxide storage in a depleted natural gas reservoir: Applied Geochemistry, v. 30, p. 16-32.De Silva, P.N.K., and P.G. Ranjith, 2014, Understanding and application of CO2 adsorption capacity estimation models for coal types: Fuel, v. 121, p. 250-259.De Silva, P.N.K., P.G. Ranjith, and S.K. Choi, 2011, A study of methodologies for CO2 storage capacity estimation of coal: Fuel, v. 91, p. 1-15.De Silva, P.N.K., P.G. Ranjith, and S.K. Choi, 2011, A study of methodologies for CO2 storage capacity estimation of coal: Fuel, v. 91, p. 1-15.De Souza, L.E., and J.F.C.L. Costa, 2013, Sample weighted variograms on the sequential indicator simulation of coal deposits: International Journal of Coal Geology, v. 112, p. 154-163.De Vries, H.A.W., P.J. Habets, and C. Bokhoven, 1968, The reflectance of bituminous coal: Brennst.-Chem., v. 49, p. 15-21, 47-52.De Wet, C.B., S.O. Moshier, J.C. Hower, A.P. De Wet, S.T. Brennan, C.T. Helfrich, and A.L. Raymond, 1997, Disrupted coal and carbonate facies within two Pennsylvanian cyclothems, southern Illinois Basin, United States: Geological Society of America Bulletin, v. 109, p. 1231-1248.Death, D.L., J.G. Haub, and J.E. Eberhardt, 1988, Macroscopic laser-induced fluorescence of coal: rank determination: Fuel, v. 67, p. 859-862.Debelak, K.A., and J.T. Schrodt, 1979, Comparison of pore structure in Kentucky coals by mercury penetration and carbon dioxide adsorption: Fuel, v. 58, p. 732-736.Decker, A.D., and D.M. Horner, 1987, Origin and production implications of abnormal coal reservoir pressure: Tuscaloosa, Alabama, Proceedings of the 1987 Coalbed Methane Symposium, paper 8714, p. 51-62.

Dawson, F.M., 1999, Coalbed methane exploration in structurally complex terrain, in M. Mastalerz, M. Glikson, and S.D. Golding, eds., Coalbed methane: scientific, environmental and economic evaluation: Boston, Kluwer Academic Publishers, p. 111-121.Dawson, F.M., A.R. Cameron, and T. Jerzykiewicz, 1989, Distribution and character of coal in the Battle River coalfield, east-central Alberta, in Contributions to Canadian coal geoscience: Geological Survey of Canada Paper 89-8, p. 49-61.

Dehmer, J., 1995, Petrological and organic geochemical investigation of recent peats with known environments of deposition: International Journal of Coal Geology, v. 28, p. 111-138.Dehmer, J., 2004, A short report of the investigations made on the facies of German coal deposits: International Journal of Coal Geology, v. 58, p. 41-51.Deisman, N., D.M. Ivars, C. Darcel, and R.J. Chalaturnyk, 2010, Empirical and numerical approaches for geomechanical characterization of coal seam reservoirs: International Journal of Coal Geology, v. 82, p. 204-212.Deisman, N., M. Khajeh, and R.J. Chalaturnyk, 2013, Using geological strength index (GSI) to model uncertainty in rock mass properties of coal for CBM/ECBM reservoir geomechanics: International Journal of Coal Geology, v. 112, p. 76-86.Deisman, N., T. Gentzis, and R.J. Chalaturnyk, 2008, Unconventional geomechanical testing on coal for coalbed reservoir well design: The Alberta Foothills and Plains: International Journal of Coal Geology, v. 51, p. 15-26.del Rio, J.C., and R.P. Philp, 1999, Field ionization mass spectrometric study of high molecular weight hydrocarbons in a crude oil and a solid bitumen: Organic Geochemistry, v. 30, p. 279-286.Delarue, F., J.-R. Disnar, Y. Copard, S. Gorgo, J. Jacob, and F. Laggoun-Défarge, 2013, Can Rock-Eval pyrolysis assess the biogeochemical composition of organic matter during peatification?: Organic Geochemistry, v. 61, p. 66-72.Delvaux, D., H. Martin, P. Leplat, and J. Paulet, 1990, Comparative Rock-Eval pyrolysis as an improved tool for sedimentary organic matter analysis: Organic Geochemistry, v. 16, p. 1221-1229.DeMaris, P.J., 2000, Formation and distribution of coal balls in the Herrin coal (Pennsylvanian), Franklin County, Illinois Basin, USA: Journal of the Geological Society, London, v. 157, p. 221-228.DeMaris, P.J., 2000, Formation and distribution of coal balls in the Herrin Coal (Pennsylvanian), Franklin County, Illinois Basin, USA: London, Journal of the Geological Society, v. 157, p. 221-228.Dembicki, H., Jr., 1992, The effects of the mineral matrix on the determination of kinetic parameters using modified Rock-Eval pyrolysis: Organic Geochemistry, v. 18, p. 531-539.Dembicki, H., Jr., 2009, Three common source rock evaluation errors made by geologists during prospect or play appraisals: AAPG Bulletin, v. 93, p. 341-356.Dembicki, H., Jr., 2009, Three common source rock evaluation errors made by geologists during prospect or play appraisals: AAPG Bulletin, v. 93, p. 341-356.Dembicki, H., Jr., 2009, Three common source rock evaluation errors made by geologists during prospect or play appraisals: AAPG Bulletin, v. 93, p. 341-356.Dembicki, H., Jr., 2009, Three common source rock evaluation errors made by geologists during prospect or play appraisals: AAPG Bulletin, v. 93, p. 341-356.Dembicki, H., Jr., B. Horsfield, and T.T.Y. Ho, 1983, Source rock evaluation by pyrolysis gas chromatography: AAPG Bulletin, v. 67, p. 1094-1103.Demchuk, T.D., 1993, Petrology of fibrous coal (fusain) and associated inertinites from the Early Paleocene of the central Alberta Plains: International Journal of Coal Geology, v. 24, p. 211-232.Demchuk, T.D., J. Shearer, and T. Moore, eds., 1995, Tertiary-age coals—GSA Symposium: International Journal of Coal Geology, v. 28, p. 71-342.Demir, I., A.A. Lizzio, E.L. Fuller, and R.D. Harvey, 1994, Surface properties of eight coals in the Illinois Basin coal sample program: Journal of Coal Quality, v. 13, p. 93-103.

Demir, I., and R.D. Harvey, 1991, Variation of organic sulfur in macerals of selected Illinois Basin coals: Organic Geochemistry, v. 17, p. 525-533.

Demir, I., D.G. Morse, S.D. Elrick, and C.A. Chenoweth, 2004, Delineation of the coalbed methane resources of Illinois: Illinois State Geological Survey Circular 564, CD-ROM.

Demir, I., R.D. Harvey, and K.C. Hackley, 1993, SEM-EDX and isotope characterization of the organic sulfur in macerals and chars in Illinois Basin coals: Organic Geochemistry, v. 20, p. 257-266.Demko, T.M., and R.A. Gastaldo, 1992, Paludal environments of the Mary Lee coal zone, Pottsville Formation, Alabama: stacked clastic swamps and peat mires: International Journal of Coal Geology, v. 20, p. 23-47.Denney, D., 2008, Coalbed-methane pilots: timing, design, and analysis: Journal of Petroleum Technology, v. 60, no. 7, p. 75-78.Denney, D., 2008, Modeling hydraulic-fracture treatments in San Juan Basin coals: Fully functional 3D fracture model: Journal of Petroleum Technology, v. 60, no. 3, p. 62-66.Dennis, R., 2007, Ion exchange helps CBM producers handle water: Oil & Gas Journal, v. 105.2, p. 41-43.DePaolo, D.J.,D.R. Cole, A. Navrotsky, and J.C. Bourg, eds., 2013, Geochemistry of geologic CO2 sequestration: Mineralogical Society of America, Reviews in Mineralogy & Geochemistry 77, 539 p.Depoi, F.S., D. Pozebon, and W.D. Kalkreuth, 2008, Chemical characterization of feed coals and combustion-by-products from Brazilian power plants: International Journal of Coal Geology, v. 76, p. 227-236.Derbyshire, F., 1991, Vitrinite structure: alterations with rank and processing: Fuel, v. 44, p. 276.Derbyshire, F., and T. Hager, 1994, Coal liquefaction and catalysis: Fuel, v. 73, p. 1087f

Derenne, S., C. Largeau, E. Casadevall, C. Berkaloff, and B. Rousseau, 1991, Chemical evidence of kerogen formation in source rocks and oil shales via selective preservation of thin resistant outer walls of microalgae: origin of ultralaminae: Geochimica et Cosmochimica Acta, v. 55, p. 1041-1050.

Decker, D., S.J. Jeu, J.D. Cooper, and D.E. Wicks, 1988, Geology, geochemistry, reservoir engineering, and completion methods at the Cedar Hill field, San Juan County, New Mexico: a field study of classic coal degasification behavior, in J.E. Fassett, ed., Geology and coal-bed methane resources of the northern San Juan basin, Colorado and New Mexico: Denver, Rocky Mountain Association of Geologists Guidebook, p. 221-235.

Demir, I., and R.D. Harvey, 1990, Abundance and origin of major minerals in the Herrin coal, Illinois basin, in Mineral matter and ash deposition from coal: New York, Engineering Foundation, p. 13-22.

Demir, I., C.-L. Chou, and C. Chaven, 1990, Abundances and leachabilities of sodium and chlorine in lithotypes of Illinois Basin coals, in L.L. Chyi and C.-L. Chou, eds., Recent advances in coal geochemistry: Geological Society of America Special Paper 248, p. 73-85.

Demir, I., R.B. Winston, and C.-L. Chou, 1987, Laboratory experiments to evaluate the removal of ash, sodium, chlorine, and sulfur from three selected samples of Illinois coal by concentrating table, jig, and froth flotation techniques, in Processing and utilization of high sulfur coals II: Elsevier, p. 121-129.

Derbyshire, F.J., A. Davis, and R. Lin, 1991, Two-component concept of coal structure, in H.H. Schobert, K.D. Bartle, and L.J. Lynch, eds., Coal science II: American Chemical Society Symposium Series 461, p. 72-88.Derbyshire, F.J., A. Davis, and R. Lin, 1991, Two-component concept of coal structure, in H.H. Schobert, K.D. Bartle, and L.J. Lynch, eds., Coal science II: Washington, D.C., American Chemical Society Symposium Series 461, p. 72-88.Derbyshire, F.J., A. Davis, and R. Lin, 1991, Two-component concept of coal structure, in H.H. Schobert, K.D. Bartle, and L.J. Lynch, eds., Coal science II: Washington, D.C., American Chemical Society Symposium Series 461, p. 72-88.

Derenne, S., F. Le Berre, C. Largeau, P. Hatcher, J. Connan, and J.F. Raynaud, 1992, Formation of ultralaminae in marine kerogens via selective preservation of thin resistant outer walls of microalgae, in C.B. Eckardt, J.R. Maxwell, S.R. Larter, and D.A.C. Manning, eds., Advances in organic geochemistry 1991, part II. Advances and applications in energy and the natural environment: Organic Geochemistry, v. 19, p. 345-350.Derenne, S., P. Metzger, C. Largeau, P.F. Van Bergen, J.P. Gatellier, J.S. Sinninghe Damsté, J.W. De Leeuw, and C. Berkaloff, 1992, Similar morphological and chemical variations of Gloecapsomorpha prisca in Ordovician sediments and cultured Botryococcus braunii as a response to changes in salinity, in C.B. Eckardt, J.R. Maxwell, S.R. Larter, and D.A.C. Manning, eds., Advances in organic geochemistry 1991, part II. Advances and applications in energy and the natural environment: Organic Geochemistry, v. 19, p. 299-313.Deul, M., 1976, Natural gas from coalbeds, in Natural gas from unconventional geologic sources: Washington, D.C., National Academy of Sciences, p. 193-205.

Deul, M., and A.G. Kim, 1975, Degasification of coalbeds - a commercial source of pipeline gas: Presented at Symposium on Clean Fuels from Coal II, Institute of Gas Technology, 14 p.Deul, M., and A.G. Kim, 1988, Methane control research: summary of results, 1964-1980: U.S. Bureau of Mines Bulletin 687, 174 p.Deul, M., and A.G. Kim, 2002, Coal beds: a source of natural gas: Oil & Gas Journal, v. 100, no. 35, p. 68, 70. (reprint of 1975 article)Deutsch, C., and B.J. Wilde, 2013, Modeling multiple coal seams using signed distance functions and global kriging: International Journal of Coal Geology, v. 112, p. 87-93.DeVanney, K., 2014, Coke petrography: The Society for Organic Petrology Newsletter, v. 31, no. 3, p. 16-19.

DeVanney, N., 2001, Impact of sample desiccation on the mean maximum vitrinite reflectance for various ranks of coal: TSOP Newsletter, v. 18, no. 3, p. 15-20.Dewing, K., and H. Sanei, 2009, Analysis of large thermal maturity datasets: Examples from the Canadian Arctic Islands: International Journal of Coal Geology, v. 77, p. 436-448.Dewing, K., and H. Sanei, 2009, Analysis of large thermal maturity datasets: Examples from the Canadian Arctic Islands: International Journal of Coal Geology, v. 77, p. 436-448.Dewing, K., and H. Sanei, 2009, Analysis of large thermal maturity datasets: Examples from the Canadian Arctic Islands: International Journal of Coal Geology, v. 77, p. 436-448.Dewing, K., and H. Sanei, 2009, Analysis of large thermal maturity datasets: Examples from the Canadian Arctic Islands: International Journal of Coal Geology, v. 77, p. 436-448.Dewing, K., and M. Obermajer, 2009, Lower Paleozoic thermal maturity and hydrocarbon potential of the Canadian Arctic Archipelago: Bulletin of Canadian Petroleum Geology, v. 57, p. 141-166.Dewing, K., and M. Obermajer, 2009, Lower Paleozoic thermal maturity and hydrocarbon potential of the Canadian Arctic Archipelago: Bulletin of Canadian Petroleum Geology, v. 57, p. 141-166.Dewing, K., and M. Obermajer, 2009, Lower Paleozoic thermal maturity and hydrocarbon potential of the Canadian Arctic Archipelago: Bulletin of Canadian Petroleum Geology, v. 57, p. 141-166. (conversion between Tmax and vitrinite reflectance equivalent, p. 149)

di Primio, R., and B. Horsfield, 2006, From petroleum-type organofacies to hydrocarbon phase prediction: AAPG Bulletin, v. 90, p. 1031-1058.

Diamond, W.P., 1982, Site-specific and regional geologic considerations for coalbed gas drainage: U.S. Bureau of Mines Information Circular 8898, 24 p.Diamond, W.P., 1987, Underground observations of mined-through stimulation treatments of coalbeds: Quarterly Review of Methane from Coal Seams Technology, v. 4, no. 4, p. 19-29.

Diamond, W.P., 1994, Methane control for underground coal mines: U.S. Bureau of Mines Information Circular 9395, 44 p. (induced fractures intercepted by mining)Diamond, W.P., 1994, Methane control for underground coal mines: U.S. Bureau of Mines, Information Circular 9395, 44 p.

Diamond, W.P., and D.C. Oyler, 1987, Effects of stimulation treatments on coalbeds and surrounding strata: U.S. Bureau of Mines, Report of Investigations 9083, 48 p. (induced fractures intercepted by mining)Diamond, W.P., and J.R. Levine, 1981, Direct method determination of the gas content of coal: procedures and results: U.S. Bureau of Mines Report of Investigations 8515, 36 p.

Diamond, W.P., C.M. McCulloch, and B.M. Bench, 1976, Use of surface joint and photolinear data for predicting subsurface coal cleat orientation: U.S. Bureau of Mines Report of Investigations 8120, 13 p.Diamond, W.P., G.W. Murrie, and C.M. McCulloch, 1976, Methane gas content of the Mary Lee Group of coalbeds, Jefferson, Tuscaloosa, and Walker Counties, Alabama: U.S. Bureau of Mines Report of Investigations 8117, 9 p.Diamond, W.P., J.C. LaScola, and D.M. Hyman, 1986, Results of direct-method determination of the gas content of U.S. coalbeds: U.S. Bureau of Mines Information Circular 9067, 95 p.Diamond, W.P., S.J. Schatzel, F. Garcia, and J.P. Ulery, 2001, The modified direct method: a solution for obtaining accurate coal desorption measurements: Tuscaloosa, Alabama, Proceedings, International Coalbed Methane Symposium, Paper 128, p. 331-342.Dias, C.L., M.L.S. Oliveira, J.C. Hower, S.R. Taffarel, R.M. Kautzmann, and L.F.O. Silva, 2014, Nanominerals and ultrafine particles from coal fires from Santa Catarina, south Brazil: International Journal of Coal Geology, v. 122, p.50-60.Dias, C.L., M.L.S. Oliveira, J.C. Hower, S.R. Taffarel, R.M. Kautzmann, and L.F.O. Silva, 2014, Nanominerals and ultrafine particles from coal fires from Santa Catarina, south Brazil: International Journal of Coal Geology, v. 122, p.50-60.Dias, R.F., M.D. Lewan, J.E. Birdwell, and M.J. Kotarba, 2014, Differentiation of pre-existing trapped methane from thermogenic methane in an igneous-intruded coal by hydrous pyrolysis: Organic Geochemistry, v. 67, p. 1-7.Díaz Aguado, M.B., and C.G. Nicieza, 2007, Control and prevention of gas outbursts in coal mines, Riosa-Olloniego coalfield, Spain: International Journal of Coal Geology, v. 69, p. 253-266.Díaz-Somoano, M., I Suárez-Ruiz, J.I.G. Alonso, J.R. Encinar, M.A. López-Antón, and M.R. Martínez-Tarazona, 2007, Lead isotope ratios in Spanish coals of different characteristics and origin: International Journal of Coal Geology, v. 71, p. 28-36.Diehl, S.F., M.B. Goldhaber, A.E. Koenig, H.A. Lowers, and L.F. Ruppert, 2012, Distribution of arsenic, selenium, and other trace elements in high pyrite Appalachian coals: Evidence for multiple episodes of pyrite formation: International Journal of Coal Geology, v. 94, p. 238-249.Diehl, S.F., M.B. Goldhaber, A.E. Koenig, H.A. Lowers, and L.F. Ruppert, 2012, Distribution of arsenic, selenium, and other trace elements in high pyrite Appalachian coals: Evidence for multiple episodes of pyrite formation: International Journal of Coal Geology, v. 94, p. 238-249.

Deul, M., 1991, Coal quality and geology, in D.C. Peters, ed., Geology in coal resource utilization: Fairfax, VA, Techbooks, p. 359-368 (available from AAPG)Deul, M., 2005, Methane from coalbeds: a reminiscence, in C.A. Sternbach, M.W. Downey, and G.M. Friedman, eds., Discoverers of the 20 th century: Perfecting the search: AAPG, p. 134-141.

DeVanney, K.F., and R.W. Stanton, 1994, Need for standardization of vitrinite reflectance measurements, in P.K. Mukhopadhyay and W.G. Dow, eds., Vitrinite reflectance as a maturity parameter: applications and limitations: Washington, D.C., American Chemical Society Symposium Series 570, p. 26-38.

Dhir, R., M.J. Mavor, and J.C. Close, 1991, Evaluation of Fruitland coal properties and development economics, San Juan Basin, Colorado and New Mexico, in S.D. Schwochow, D.K. Murray, and M.F. Fahy, eds., Coalbed methane of western North America: Denver, CO, Rocky Mountain Association of Geologists Guidebook, p. 287-295.

Diamond, W.P., 1979, Evaluation of the methane gas content of coalbeds: part of a complete coal exploration program for health and safety and resource evaluation, in G.O. Argall, Jr., ed., Coal exploration, v. 2: Denver, Proceedings of the second International Coal Exploration Symposium, p. 211-227.

Diamond, W.P., 1993, Methane control for underground coal mines, in B.E. Law and D.D. Rice, eds., Hydrocarbons from coal: AAPG Studies in Geology 38, p. 237-267.Diamond, W.P., 1993, Methane control for underground coal mines, in B.E. Law and D.D. Rice, eds., Hydrocarbons from coal: AAPG Studies in Geology 38, p. 237-267.

Diamond, W.P., A.T. Iannacchione, D.G. Puglio, and P.F. Steidl, 1988, Geologic studies of gassy coalbeds, in M. Deul and A.G. Kim, Methane control research: summary of results, 1964-80: U.S. Bureau of Mines Bulletin 687, p. 41-78.

Diamond, W.P., and S.J. Schatzel, 1998, Measuring the gas content of coal: a review, in R.M. Flores, ed., Coalbed methane: from coal-mine outbursts to a gas resource: International Journal of Coal Geology, v. 35, p. 311-331.Diamond, W.P., C.H. Elder, and P.W. Jeran, 1988, Influence of geology on methane emission from coal, in M. Deul and A.G. Kim, Methane control research: summary of results, 1964-80: U.S. Bureau of Mines Bulletin 687, p. 26-40.

Diehl, S.F., M.B. Goldhaber, and J.R. Hatch, 2004, Modes of occurrence of mercury and other trace elements in coals from the Warrior field, Black Warrior Basin, northwestern Alabama: International Journal of Coal Geology, v. 59, p. 193-208.Diessel, C., R. Boyd, J. Wadsworth, D. Leckie, and G. Chalmers, 2000, On balanced and unbalanced accommodation/peat accumulation ratios in the Cretaceous coals from Gates Formation, western Canada, and their sequence-stratigraphic significance: International Journal of Coal Geology, v. 43, p. 143-186.

Diessel, C.F.K., 1983, Carbonisation reaction of inertinite macerals in Australian coals: Fuel, v. 62, p. 883-892.Diessel, C.F.K., 1983, Carbonization reactions of inertinite macerals in Australian coals: Fuel, v. 62, p. 883-892.Diessel, C.F.K., 1985, Fluorometric analysis of inertinite: Fuel, v. 64, p. 1542-1546.

Diessel, C.F.K., 1992, Coal-bearing depositional systems: Berlin, Springer-Verlag, 721 p.Diessel, C.F.K., 1992, Coal-bearing depositional systems: New York, Springer-Verlag, 721 p.Diessel, C.F.K., 1992, Coal-bearing depositional systems: New York, Springer-Verlag, 721 p.Diessel, C.F.K., 1992, The nature of inertinite and its effect on hydrogenation, carbonization and combustion (abstract): TSOP Abstracts and Program, v. 9, p. 3-6.

Diessel, C.F.K., 2007, Utility of coal petrology for sequence-stratigraphic analysis: International Journal of Coal Geology, v. 70, p. 3-34.Diessel, C.F.K., 2010, The stratigraphic distribution of inertinite: International Journal of Coal Geology, v. 81, p. 251-268.Diessel, C.F.K., and E. Wolff-Fischer, 1987, Coal and coke petrographic investigations into the fusibility of Carboniferous and Permian coking coals: International Journal of Coal Geology, v. 9, p. 87-108.

Diessel, C.F.K., and L. Gammidge, 1998, Isometamorphic variations in the reflectance and fluorescence of vitrinite — a key to depositional environment: International Journal of Coal Geology, v. 37, p. 179-206.Diessel, C.F.K., and L. Gammidge, 1998, Isometamorphic variations in the reflectance and fluorescence of vitrinite—a key to depositional environment: International Journal of Coal Geology, v. 37, p. 179-206.

Díez, M.A., R. Alvarez, and C. Barriocanal, 2002, Coal for metallurgical coke production: predictions of coke quality and future requirements for cokemaking: International Journal of Coal Geology, v. 50, p. 389-412.

Dill, H.G., J. Kus, R. Dohrmann, and Y. Tsoy, 2008, Supergene and hypogene alteration in the dual-use kaolin-bearing coal deposit Angren, SE Uzbekistan: International Journal of Coal Geology, v. 75, p. 225-240.DiMichele, W.A., and T.L. Phillips, 1985, Arborescent lycopod reproduction and paleoecology in a coal-swamp environment of late Middle Pennsylvanian age (Herrin coal, Illinois, USA): Review of Palaeobotany and Palynology, v. 44, p. 1-26.DiMichele, W.A., and T.L. Phillips, 1994, Paleobotanical and paleoecological constraints on models of peat formation in the Late Carboniferous of Euramerica: Palaeogeology, Palaeoclimate, Palaeoecology, v. 106, p. 39-90.DiMichele, W.A., C.B. Cecil, I.P. Montañez, and H.J. Falcon-Lang, 2010, Cyclic changes in Pennsylvanian paleoclimate and effects on floristic dynamics in tropical Pangaea: International Journal of Coal Geology, v. 83, p. 329-344.

DiMichele, W.A., T.L. Phillips, and W.J. Nelson, 2002, Place vs. time and vegetational persistence: a comparison of four tropical mires from the Illinois Basin during the height of the Pennsylvanian ice age: International Journal of Coal Geology, v. 50, p. 43-72.Dittrick, P., 2008, US oil shale resources look promising yet still uncertain: Oil & Gas Journal, v. 106.39, p. 22-26.Dittrick, P., 2010, DOE partnerships testing CO2 EOR, sequestration synergies: Oil & Gas Journal, v. 108.13, p. 18-20.Dobell, P., A.R. Cameron, and W.D. Kalkreuth, 1984, Petrographic examination of low-rank coals from Saskatchewan and British Columbia, Canada, including reflected and fluorescent light microscopy, SEM, and laboratory oxidation procedures: Canadian Journal of Earth Sciences, v. 21, p. 1209-1228.Dobell, P., A.R. Cameron, and W.D. Kalkreuth, 1984, Petrographic examination of low-rank coals from Saskatchewan and British Columbia, Canada, including reflected and fluorescent light microscopy, SEM, and laboratory oxidation procedures: Canadian Journal of Earth Sciences, v. 21, p. 1209-1228.Dobell, P., A.R. Cameron, and W.D. Kalkreuth, 1984, Petrographic examination of low-rank coals from Saskatchewan and British Columbia, Canada, including reflected and fluorescent light microscopy, SEM, and laboratory oxidation procedures: Canadian Journal of Earth Sciences, v. 21, p. 1209-1228.

Doelling, H.H., A.D. Smith, and F.D. Davis, 1979, Methane content of Utah coals: Utah Geological and Mineralogical Survey Special Studies 49, 102 p.Doher, L.I., 1980, Palynomorph preparation procedures currently used in the paleontology and stratigraphy laboratories, U.S. Geological Survey: U.S. Geological Survey Circular 830, 29 p.

Diessel, C.F.K., 1982, An appraisal of coal facies based on maceral characteristics, in C.W. Mallett, ed., Coal resources: origin, exploration and utilization in Australia, Proceedings: Geological Society of Australia Coal Group Symposium, Australian Coal Geology, v. 4, p. 474-483.Diessel, C.F.K., 1982, An appraisal of coal facies based on maceral characteristics, in C.W. Mallett, ed., Coal resources—origin, exploration and utilization in Australia: Geological Society of Australia Coal Group Symposium, Proceedings, p. 474-483.

Diessel, C.F.K., 1985, Macerals as coal facies indicators: 10th Interntional Congress of Carboniferous Stratigraphy and Geology, Madrid, Compte Rendu, v. 3, p. 367-373.Diessel, C.F.K., 1986, On the correlation between coal facies and depositional environments, in Advances in the study of the Sydney basin: Proceedings of the 20 th Newcastle Symposium, Newcastle, N.S.W., The University of Newcastle, Publication 246, p. 19-22.Diessel, C.F.K., 1986, On the correlation between coal facies and depositional environments, in Advances in the study of the Sydney Basin: Proceedings of the 20 th Newcastle Symposium, The University of Newcastle, Publication 246, p. 19-22.

Diessel, C.F.K., 1998, Sequence stratigraphy applied to coal seams: two case histories, in K.W. Stanley and P.J. McCabe, eds., Relative role of eustacy, climate and tectonism in continental rocks: SEPM Special Publication 59, p. 151-173.

Diessel, C.F.K., and E. Wolff-Fischer, 1989, The application of fluorescence intensity measurements of vitrinite to questions of coal formation, in C.G. Thomas and M.G. Strachan, eds., Proceedings of the Macerals ’89 symposium: North Ryde, NSW, CSIRO, p. 12-1 to 12-10.

Diessel, C.F.K., and M. Smyth, 1995, Petrographic constituents of Australian coals, in C.R. Ward, and others, eds., Geology of Australian coal basins: Geological Society of Australia Coal Geology Group, Special Publication 1, p. 63-81.Diessel, C.F.K., and R.E. Guyot, 1985, Petrographic studies on solid residues derived from the hydrogenation of some Australian coals, in A.T. Cross, ed., Economic geology: coal, oil and gas: Neuvieme Congres International de Stratigraphie et du Geologie du Carbonifere, Compte Rendu, v. 4, Southern Illinois University Press, p. 573-580.

Dill, H.G., and H. Pöhlmann, 2002, Chemical composition and mineral matter of paralic and limnic coal types of lignite through anthracite rank (Germany), in L.V. Hills, C.M. Henderson, and E.W. Bamber, eds., Carboniferous and Permian of the World: XIV ICCP Proceedings: Canadian Society of Petroleum Geologists Memoir 19, p. 851-867.

DiMichele, W.A., M.O. Rischbieter, D.L. Eggert, and R.A. Gastaldo, 1984, Stem and leaf cuticle of Karinopteris: source of cuticles from the Indiana ‘paper’coal: American Journal of Botany, v. 71, p. 626-637.

DOE/EA, 2002, Enhanced coalbed methane production and sequestration of CO2 in unmineable coal seams: DOE National Energy Technology Laboratory, Environmental assessment, DOE/EA-1420. http://www.netl.doe.gov/ISO14001/esh-ism/EA/pubs/Consol_drftEA.PDF

Donaldson, A.C., and C. Eble, 1991, Pennsylvanian coals of central and eastern United States, in H.J. Gluskoter, D.D. Rice, and R.B. Taylor, eds., Economic geology, U.S.: Geological Society of America, The geology of North America, v. P-2, p. 523-546.Donaldson, A.C., J.J. Renton, and M.W. Presley, 1985, Pennsylvanian deposystems and paleoclimates of the Appalachians, in T.L. Phillips and C.B. Cecil, eds., Paleoclimatic controls on coal resources of the Pennsylvanian System of North America: International Journal of Coal Geology, v. 5, p. 167-193.

Donaldson, A.C., M.W. Presley, and J.J. Renton, eds., 1979, Carboniferous coal short course and guidebook: West Virginia Geological and Economic Survey, Bulletin B-37, 656 p.Donda, F., D. Civile, E. Forlin, V. Volpi, M. Zecchin, E. Gordini, B. Merson, and L. De Santis, 2013, The northernmost Adriatic Sea: a potential location for CO2 geological storage?: Marine and Petroleum Geology, v. 42, p. 148-159.

Donnell, J.R., and R.W. Blair, 1970, Resource appraisal of three rich oil-shale zones in the Green River Formation, Piceance Creek Basin, Colorado: Colorado School of Mines Quarterly, v. 65, p. 73-87.Donovan, W.S., 2000, Mudlogging method calculates coalbed gas content: Oil & Gas Journal, v. 98, no. 7, p. 64-67.Dormans, H.N.M., F.J. Huntjens, and D.W. van Krevelen, 1957, Chemical structure and properties of coal – composition of the individual macerals (vitrinites, fusinites, micrinites and exinites): Fuel, v. 36, p. 321-339.Dormans, H.N.M., F.J. Huntjens, and D.W. van Krevelen, 1957, Chemical structure and properties of coal. XX. Composition of the individual macerals (vitrinites, fusinites, micrinites and exinites): Fuel, v. 36, p. 321-333.Dormans, H.N.M., F.J. Huntjens, and D.W. van Krevelen, 1957, Chemical structure and properties of coal—composition of the individual macerals (vitrinites, fusinites, micrinites and exinites): Fuel, v. 36, p. 321-339.Doscher, T.M., V.A. Kuusdraa, and E. Hammerschaib, 1981, The controlling production mechanism of methane gas from coalbeds: Enegy Sources, v. 5, p. 71-84.

Douglas, P.L., S.C. Lythgoe, and S.K. Mallik, 1994, Coal liquefaction modeling: 1) development of a kinetic model, 2) parameter estimation: Fuel, v. 73, p. 531, 542.Dow, W.G., 1977, Kerogen studies and geological interpretations: Journal of Geochemical Exploration, v. 7, p. 79-99.Dow, W.G., 1977, Kerogen studies and geological interpretations: Journal of Geochemical Exploration, v. 7, p. 79-99.

Draffin, C.W., and others, 1979, Underground coal conversion - program description: USDOE ET-0100, 68 p.Drake, R.M., II, S.T. Brennan, J.A. Covault, M.S. Blondes, P.A. Freeman, S.M. Cahan, C.A. DeVera, and C.D. Lohr, 2012, Geologic framework for the national assessment of carbon dioxide storage resources—Denver Basin, Colorado, Wyoming, and Nebraska: U.S. Geological Survey Open-File Report 2012-1024-G, 17 p.Dresen, L., and H. Rüter, 1994, Seismic coal exploration. Part B: in-seam seismics: New York, Pergamon Press, Handbook of Geophysical Exploration, section 1. Seismic Exploration, v. 16B, 433 p.

Drobniak, A., M. Mastalerz, J. Rupp, and N. Eaton, 2004, Evaluation of coalbed gas potential of the Seelyville coal member, Indiana, USA: International Journal of Coal Geology, v. 57, p. 265-282.Du, G., X. Zhuang, X. Querol, M. Izquierdo, A. Alastuey, T. Moreno, and O. Font, 2009, Ge distribution in the Wulantuga high-germanium coal deposit in the Shengli coalfield, Inner Mongolia, northeastern China: International Journal of Coal Geology, v. 78, p. 16-26.Duan, Y., T. Sun, Y. Qian, J. He, X. Zhang, L. Xu, and B. Wu, 2012, Pyrolysis experiments of forest marsh peat samples with different maturities: An attempt to understand the isotopic fractionation of coalbed methane during staged accumulation: Fuel, v. 94, p. 480-485.Duber, S., S. Pusz, B.K. Kwiecińska, and J.N. Rouzaud, 2000, On the optically biaxial character and heterogeneity of anthracites: International Journal of Coal Geology, v. 44, p. 227-250.Ducazeaux, J., K. Le Tran, and G. Nicolas, 1991, Brent coal typing by combined optical and geochemical studies: Bulletin Centres Recherches Exploration-Production, Elf Aquitaine, v. 15, p. 369-381.Duda, J.R., V. Kuuskraa, M. Godec, and T. Van Leeuwen, 2010, Modeling exercises assess US CO2-EOR potential: Oil & Gas Journal, v. 108.13, p. 52-55.Dudzińska, A., 2014, Investigation of adsorption and desorption of acetylene on hard coal samples from Polish mines: International Journal of Coal Geology, v. 128-129, p. 24-31.Dudzińska, A., 2014, Investigation of adsorption and desorption of acetylene on hard coal samples from Polish mines: International Journal of Coal Geology, v. 128-129, p. 24-31.Duey, R., 2010, Oil shale may put Jordan on the road to energy independence: Hart’s E&P, v. 83, no. 1, p. 63.Duey, R., 2013, CBM aids Asian markets: Hart Energy Publishing, E&P, v. 86, no. 8, p. 82, 84-85.Dulhunty, J.A., 1944, Origin of the New South Wales torbanites: Linnean Society of New South Wales, Proceedings, v. 69, p. 26-48.

Duncan, D.C., and V.E. Swanson, 1965, Organic-rich shale of the United States and world land areas: U.S. Geological Survey Circular 523, 30 p.Dunham, G.E., R.A. DeWall, and C.L. Senior, 2003, Fixed-bed studies of the interactions between mercury and coal combustion fly ash: Fuel Processing Technology, v. 82, p. 197-213.Dunlop, N.F., and R.B. Johns, 1999, Thermally induced chemical changes in the macromolecular structure of an Indonesian coal: Organic Geochemistry, v. 30, p. 1301-1309.

Dong, X., and D. Drysdale, 1995, Retardation of the spontaneous ignition of bituminous coal, in J.A. Pajares and J.M.D. Tascon, eds., Coal science: New York, Elsevier, Coal Science and Technology 24, v. 1, p. 501-504.Donnell, J.R., 1991, Oil shale, in H.J. Gluskoter, D.D. Rice, and R.B. Taylor, eds., Economic geology, U.S.: Boulder, Colorado, Geological Society of America, The Geology of North America, v. P-2, p. 183-188.

Douglas, A.G., and P.J. Grantham, 1974, Fingerprint gas chromatography in the analysis of some native bitumens, asphalts and related substances, in B. Tissot and F. Bienner, eds., Advances in Organic Geochemistry 1973: Paris, Editions Technip, p. 261-276.

Dow, W.G., and D.I. O'Connor, 1982, Kerogen maturity and type by reflected light microscopy applied to petroleum exploration, in F.L. Staplin, and others, How to assess maturation and paleotemperatures: S.E.P.M. Short Course 7, p. 133-157.Dow, W.G., and D.I., O'Connor, 1982, Kerogen maturity and type by reflected light microscopy applied to petroleum exploration, in F.L. Staplin and others, How to assess maturation and paleotemperatures: SEPM Short Course 7, p. 133-157.

Dressel, B., and D. Olsen, 2010, Geologic storage formation classifications: understanding its importance and impacts on CCS opportunities in the United States: U.S. Department of Energy, National Energy Technology Laboratory, 56 p. http://www.fe.doe.gov/news/techlines/2010/10050-Geologic_Storage_Manual_Issued.html

Dumitrescu, M., D.B. Finkelstein, R.O. Lazar, J. Schieber, and S.C. Brassell, 2004, Origin and history of bitumen in geodes of the New Albany Shale, in J. Schieber and R. Lazar, eds., Devonian black shales of the eastern U.S.: New insights into sedimentology and stratigraphy from the subsurface and outcrops in the Illinois and Appalachian Basins: Indiana Geological Survey Open-File Study 04-05, p. 61-67.Duncan, D.C., 1976, Geologic setting of oil shales and world prospects, in T.F. Yen and G.V. Chilingarian, eds., Oil shale: Elsevier, p. 13-26.

Durand, B., 1980, Sedimentary organic matter and kerogen. Definition and quantitative importance of kerogen, in B. Durand, ed., Kerogen. Insoluble organic matter from sedimentary rocks: Paris, Editions Technip, p. 13-34.Durand, B., A.Y. Huc, and J.L. Oudin, 1987, Oil saturation and primary migration: observations from the Kerbau wells, Mahakam delta, Indonesia, in B. Doligez, ed., Migration of hydrocarbons in sedimentary basins: Paris, Editions Technip, Collection Colloques et Seminaires, v. 45, p. 173-195.Durand, B., and G. Nicaise, 1980, Procedures for kerogen isolation, in B. Durand, ed., Kerogen -- insoluble organic matter from sedimentary rocks: Paris, Editions Technip, p. 35-53.Durand, B., and M. Paratte, 1983, Oil potential of coals: a geochemical approach, in J. Brooks, ed., Petroleum geochemistry and exploration of Europe: Boston, Blackwell Scientific Publications, p. 255-265.Durand, B., and M. Paratte, 1983, Oil potential of coals: a geochemical approach, in J. Brooks, ed., Petroleum geochemistry and exploration of Europe: Boston, Blackwell Scientific Publications, The Geological Society, Special Publication 12, p. 255-265. (Tmax vs. Ro, p. 264)

Durucan, S., and J.-Q. Shi, 2009, Improving the CO2 well injectivity and enhanced coalbed methane production performance in coal seams: International Journal of Coal Geology, v. 77, p. 214-221.Dushenko, V., H. Mere, I. Shcheglov, T. Tiikma, and A. Vrager, 2004, Laboratory test rig for combusting Estonian oil shale in circulating fluidized bed: Oil Shale, v. 21, p. 161-172.Dutcher, L.A.F., and J.C. Crelling, 2000, History of applied coal petrology in the United States, I. Early history of the application of coal petrography in the steel industry: International Journal of Coal Geology, v. 42, p. 93-101.Dutcher, L.A.F., and J.C. Crelling, 2000, History of applied coal petrology in the United States. I. Early history of the application of coal petrography in the steel industry: International Journal of Coal Geology, v. 42, p. 93-101.Dutcher, R. R., ed., 1978, Field description of coal: Philadelphia, American Society for Testing and Materials Special Technical Publication 661, 71 p.

Dutcher, R.R., ed., 1978, Field description of coal: ASTM STP 661, 71 p.

Dutta, P., S. Bhowmik, and S. Das, 2011, Methane and carbon dioxide sorption on a set of coals from India: International Journal of Coal Geology, v. 85, p. 289-299.Dutta, P., S. Bhowmik, and S. Das, 2011, Methane and carbon dioxide sorption on a set of coals from India: International Journal of Coal Geology, v. 85, p. 289-299.Dutta, P., S. Harpalani, and B. Prusty, 2008, Modeling of CO2 sorption on coal: Fuel, v. 87, p. 2023-2036.Dutta, P., S. Harpalani, and B. Prusty, 2008, Modeling of CO2 sorption on coal: Fuel, v. 87, p. 2023-2036.Dutta, S., M. Mallick, K. Kumar, U. Mann, and P.F. Greenwood, 2011, Terpenoid composition and botanical affinity of Cretaceous resins from India and Myanmar: International Journal of Coal Geology, v. 85, p. 49-55.Dutta, S., M. Mallick, N. Bertram, P.F. Greenwood, and R.P. Mathews, 2009, Terpenoid composition and class of Tertiary resins from India: International Journal of Coal Geology, v. 80, p. 44-50.Dutta, S., R.P. Mathews, B.D. Singh, S.M. Tripathi, A. Singh, P.K. Saraswati, S. Banerjee, and U. Mann, 2011, Petrology, palynology and organic geochemistry of Eocene lignite of Matanomadh, Kutch Basin, western India: Implications to depositional environment and hydrocarbon source potential: International Journal of Coal Geology, v. 85, p. 91-102.Dutta, S., R.P. Mathews, B.D. Singh, S.M. Tripathi, A. Singh, P.K. Saraswati, S. Banerjee, and U. Mann, 2011, Petrology, palynology and organic geochemistry of Eocene lignite of Matanomadh, Kutch Basin, western India: Implications to depositional environment and hydrocarbon source potential: International Journal of Coal Geology, v. 85, p. 91-102.Duttlinger, D., 2004, Enhanced recovery intertwines naturally with CO2 sequestration: The American Oil & Gas Reporter, v. 47, no. 1, p. 29.Dyni, J.R., 2003, Geology and resources of some world oil-shale deposits: Oil Shale, v. 20, p. 193-252.

Dyni, J.R., 2006, Oil shale developments in the United States: Oil Shale, v. 23, p. 97-98.

Dyni, J.R., and R.C. Johnson, 2006, Will oil shale be a major player?: AAPG Explorer, v. 27, no. 5, p. 41, 39.Dyni, J.R., ed., 2003, Unconventional energy resources of North America: AAPG Special Publication, EMD Poster.Dyrkacz, G.R., and E.P. Horwitz, 1982, Separation of coal macerals: Fuel, v. 61, p. 3-12.Dyrkacz, G.R., C.A.A. Bloomquist, and L. Ruscic, 1991, An investigation of the vitrinite maceral group in microlithotypes using density gradient separation method: Energy and Fuels, v. 5, p. 155-163.Dzou, L.I.P., R.A. Noble, and J.T. Senftle, 1995, Maturation effects on absolute biomarker concentration in a suite of coals and associated vitrinite concentrates: Organic Geochemistry, v. 23, p. 681-697.Eakin, P.A., and A.P. Gize, 1992, Reflected-light microscopy of uraniferous bitumens: Mineralogical Magazine, v. 56, p. 85-99.Earle, C.J., L.B. Brubaker, and P.M. Anderson, 1996, Charcoal in north central Alaskan lake sediments: relationships to fire and late-Quaternary vegetation history: Review of Palaeobotany and Palynology, v. 92, p. 83-95.

Eavenson, H.N., 1935, Coal through the ages (second edition): New York, AIME, 123 p.Eberhardt, J.E., T.H. Nguyen, and R. Read, 1992, Fluorescence alteration of coal and polycyclic aromatic hydrocarbons: Organic Geochemistry, v. 18, p. 145-153.Ebers, M.L., 2009, Kansas CBM well flow rates correlate to coal gas content: Oil & Gas Journal, v. 107.24, p. 34-40.

Eble, C.F., 2012, Organic petrology of Carbondale Formation coal beds and marine roof shales in western Kentucky, eastern Interior (Illinois) Basin, USA: International Journal of Coal Geology, v. 104, p. 60-69.

Durand, B., B. Alpern, J.L. Pittion, and B. Pradier, 1986, Reflectance of vitrinite as a control of thermal history of sediments, in J. Burrus, ed., Thermal modeling in sedimentary basins: Paris, Editions Technip, p. 441-474.Durand, B., B. Alpern, J.L. Pittion, and B. Pradier, 1986, Reflectance of vitrinite as a control of thermal history of sediments, in J. Burruss, ed., Thermal modeling in sedimentary basins: Paris, Editions Technip, p. 441-474.Durham, L.S., 2007, Demonstration being monitored, corralling CO2 a win-win for oil: AAPG Explorer, v. 28, no. 7, p. 16-18. http://www.aapg.org/explorer/2007/07jul/carbon_sequestration.cfm

Dutcher, R.R., E.W. White, and W. Spackman, 1964, Elemental ash distribution in coal components – use of the electron probe: Proceedings of the 22 nd Ironmaking Conference, Iron and Steel Division, The Metallurgical Society of A.I.M.M.E., p. 463-483.

Dutcher, R.R., J.C. Crelling, and M.C. Cascia, 1982, Petrography and fluorescence properties of bituminous coals of the Spanish Peaks region, Colorado, in K.D. Gurgel, ed., Proceedings of the fifth symposium on the geology of Rocky Mountain coal—1982: Utah Geological and Mineral Survey, Bulletin 118, p. 179-186.

Dyni, J.R., 2006, Geology and resources of some world oil-shale deposits: USGS Scientific Investigations Report 2005-5294, 42 p. (http://pubs.usgs.gov/sir/2005/5294/)

Dyni, J.R., 2008, Preliminary stratigraphic cross sections of oil shale in the Eocene Green River Formation, Uinta Bsain, Utah: U.S. Geological Survey Open-File Report 2008-1220, 11 p. http://pubs.usgs.gov/of/2008/1220/Dyni, J.R., and others, 1989, Comparison of hydroretorting, Fischer assay, and Rock-Eval analyses of some world oil shales, in Proceedings 1989 Eastern Oil Shale Symposium: Lexington, University of Kentucky Institute for Mining and Minerals Research, p. 270-286.

East, J.A., 2013, Coal fields of the conterminous United States: National coal resource assessment updated version: U.S. Geological Survey, Open-File Report 2012-1205, one sheet. http://pubs.usgs.gov/of/2012/1205/ Eaton, S.R., 2006, Cleats are keys to solid footing: AAPG Explorer, v. 27, no. 11, p. 22. (http://www.aapg.org/explorer/2006/11nov/horseshoe_side.cfm) Eaton, S.R., 2006, Coalbed gas frontier being tapped: AAPG Explorer, v. 27, no. 11, p. 20, 24. (http://www.aapg.org/explorer/2006/11nov/horseshoe_canyon.cfm)

Eble, C.F., 1994, Applications of coal palynology to biostratigraphic and paleoecologic analyses of Pennsylvanian coal beds, in C.B. Cecil and N.T. Edgar, eds., Predictive stratigraphic analysis—concept and application: U.S. Geological Survey Bulletin 2110, p. 28-32.Eble, C.F., 1996, Paleoecology of Pennsylvanian coal beds in the Appalachian Basin, in J. Jansonius and D.C. McGregor, eds., Palynology: principles and applications: American Association of Stratigraphic Palynologists, v. 3, p. 1143-1156.

Eble, C.F., 2012, Organic petrology of Carbondale Formation coal beds and marine roof shales in western Kentucky, eastern Interior (Illinois) Basin, USA: International Journal of Coal Geology, v. 104, p. 60-69. (visual kerogen on whole rock)

Eble, C.F., R.A. Gastaldo, T.M. Demko, and Y. Liu, 1994, Coal compositional changes along a mire interior to mire margin transect in the Mary Lee coal bed, Warrior Basin, Alabama, USA: International Journal of Coal Geology, v. 26, p. 43-62.

Ebukanson, E.J., and R.R.F. Kinghorn, 1985, Kerogen facies in the major Jurassic mudrock formations of southern England and the implication on the depositional environments of their precursors: Journal of Petroleum Geology, v. 8, p. 435-462.Echols, J.B., 2000, Coalbed methane: Louisiana’s unexplored energy resource: Louisiana State University, Basin Research Institute (BRI) Bulletin, v. 9, p. 18-27.Edman, J.D., and R.C. Surdam, 1984, Influence of overthrusting on maturation of hydrocarbons in Phosphoria Formation, Wyoming-Idaho-Utah Overthrust Belt: AAPG Bulletin, v. 68, p. 1803-1817.Edmunds, W.E., 2002, Coal in Pennsylvania: Pennsylvania Geological Survey, Educational Series 7, 28 p.Eggert, D.L., and T.L. Phillips, 1982, Environments of deposition - coal balls, cuticular shale, and gray-shale floras in Fountain and Parke Counties, Indiana: Indiana Geological Survey Special Report 30, 43 p.Eggert, D.L., and T.L. Phillips, 1982, Environments of deposition—coal balls, cuticular shale and gray-shale floras in Fountain and Parke Counties, Indiana: Indiana Department of Natural Resources, Special Report 30, 43 p.

Eggleston, J.R., M.D. Carter, and J.C. Cobb, 1990, Coal resources available for development—a methodology and pilot study: U.S. Geological Survey Circular 1055, 15 p.

Ekinci, E., M. Tolay, K.D. Bartle, and N. Taylor, 1988, Rapid characterization of lignite liquefaction products: Erdöl und Kohle-Erdgas-Petrochemie, v. 41, no. 7-8, p. 303-305.Ekmann, J.M., S.M. Smouse, J.C. Winslow, M. Ramezan, and N.S. Harding, 1996, Cofiring of coal and waste: London, IEA Coal Research, IEACR/90, 68 p.Elder, C.H. and M. Deul, 1974, Degasification of the Mary Lee coalbed near Oak Grove, Jefferson County, Alabama, by vertical borehole in advance of mining: U.S. Bureau of Mines Report of Investigations 7968, 21 p.Elder, C.H., 1977, Effects of hydraulic stimulation on coalbeds and associated strata: U.S. Bureau of Mines Report of Investigations 8260, 20 p.Elder, C.H., and M. Deul, 1975, Hydraulic stimulation increases degasification rate of coal beds: U.S. Bureau of Mines Report of Investigations 8047, 17 p.Elick, J.M., 2011, Mapping the coal fire at Centralia, PA using thermal infrared imagery: International Journal of Coal Geology, v. 87, p. 197-203.Elick, J.M., 2013, The effect of abundant precipitation on coal fire subsidence and its implications in Centralia, PA: International Journal of Coal Geology, v. 105, p. 110-119.Elie, M., P. Faure, R. Michels, P. Landais, and L. Griffault, 2000, Natural and laboratory oxidation of low-organic-carbon-content sediments: comparison of chemical changes in hydrocarbons: Energy & Fuels, v. 14, p. 854-861.Ellacott, M.V., N.J. Russell, and R.W.T. Wilkins, 1994, Troubleshooting vitrinite reflectance problems using FAMM. A Gippsland and Otway Basin case study: APEA Journal, v. 34, p. 216-230.Ellacott, M.V., N.J. Russell, and R.W.T. Wilkins, 1994, Troubleshooting vitrinite reflectance problems using FAMM: A Gippsland and Otway Basin case study: APEA Journal, v. 34, p. 216-230.Ellenbecker, S., 2009, Technology key in directional program: American Oil & Gas Reporter, v. 52, no. 12, p. 70-71.Ellin, S., and D. McLean, 1994, The use of microwave heating in hydrofluoric acid digestions for palynological preparations: Palynology, v. 18, p. 23-31.Elswick, E.R., J.C. Hower, A.M. Carmo, T. Sun, and S.M. Mardon, 2007, Sulfur and carbon isotope geochemistry of coal and derived coal-combustion by-products: An example from an eastern Kentucky mine and power plant: Applied Geochemistry, v. 22, p. 2065-2077.

Ely, J.W., and S.A. Holditch, 1990, Fracturing techniques depend on coal seam characteristics: Oil & Gas Journal, v. 88, no. 30, p. 33-37.

Engel, M.H., and S. Macko, 1993, Organic geochemistry; principles and applications: New York, Plenum Press, 861 p.Engelder, T., and A. Whitaker, 2006, Early jointing in coal and black shale: evidence for an Appalachian-wide stress field as a prelude to the Alleghanian orogeny: Geology, v. 34, p. 581-584. (cleat formation)England, B.K., K.A. Mikka, and E.J. Bagnall, 1979, Petrographic characterization of coal using automated image analysis: Journal of Microscopy, v. 116, pt. 3, p. 329-336.Engle, M.A., L.F. Radke, E.L. Heffern, J.M.K. O’Keefe, C.D. Smeltzer, J.C. Hower, J.M. Hower, A. Prakash, A. Kolker, R.J. Eatwell, A. ter Schure, G. Queen, K.L. Aggen, G.B. Stracher, K.R. Henke, R.A. Olea, and Y. Román-Colón, 2011, Quantifying greenhouse gas emissions from coal fires using airborne and ground-based methods: International Journal of Coal Geology, v. 88, p. 147-151.Engle, M.A., R.A. Olea, J.M.K. O-Keefe, J.C. Hower, and M.J. Geboy, 2013, Direct estimation of diffuse gaseous emissions from coal fires: Current methods and future directions: International Journal of Coal Geology, v. 112, p. 164-172.Englund, K.J., H.H. Arndt, W.H. Gillespie, T.W. Henry, and H.W. Pfefferkorn, 1977, A field guide to proposed Pennsylvanian System stratotype, West Virginia: AAPG Annual Meeting, Washington, D.C., 80 p.Enick, R., J. Ammer, and W. Schuller, 2012, Mobility and conformance control for carbon dioxide EOR–Part 1: World Oil, v. 233, no. 3, p. 89-91.

Eble, C.F., and W.C. Grady, 1993, Palynologic and petrographic characteristics of two Middle Pennsylvanian coal beds and a probable modern analogue, in J.C. Cobb and C.B. Cecil, eds., Modern and ancient coal-forming environments: Geological Society of America Special Paper 286, p. 119-138.

Eble, C.F., W.C. Grady, and B.S. Pierce, 2006, Compositional characteristics and inferred origin of three Late Pennsylvanian coal beds from the northern Appalachian Basin, in S.F. Greb and W.A. DiMichele, eds., Wetlands through time: Geological Society of America Special Paper 399, p. 197-222.

Eggleston, J.R., and R.B. Finkelman, 1995, Environmental aspects of carbonate use in energy generation, in L.M.H. Carter, ed., Energy and the environment — application of geosciences to decision-making: U.S. Geological Survey Circular 1108, p. 102-103. (fluidized bed combustion)

EIA, 1998, Greenhouse gases, global climate change, and energy: EIA brochure. http://www.eia.doe.gov/oiaf/1605/ggccebro/chapter1.htmlEIA, 2002, Emissions of greenhouse gases in the United States 2001: EIA-0573(2001). ftp://ftp.eia.doe.gov/pub/oiaf/1605/cdrom/pdf/ggrpt/057301.pdf EIA, 2007, U.S. coalbed methane status map: http://www.eia.doe.gov/oil_gas/rpd/cbmusa1.pdf EIA, 2007, U.S. coalbed methane: past, present and future: http://www.eia.doe.gov/oil_gas/rpd/cbmusa2.pdf Eisenhut, W., 1981, High temperature carbonization, in M.A. Elliot, ed., Chemistry of coal utilization, second supplementary volume: New York, John Wiley and Sons, p. 847-917.

Ely, J., S.A. Holditch, and R.H. Carter, 1988, Improved hydraulic fracturing strategy for Fruitland Formation coal-bed methane recovery, San Juan basin, New Mexico and Colorado, in J.E. Fassett, ed., Geology and coal-bed methane resources of the northern San Juan basin, Colorado and New Mexico: Denver, Rocky Mountain Association of Geologists Guidebook, p. 155-158.

Enever, J., D. Casey, and M. Bocking, 1999, The role of in-situ stress in coalbed methane exploration, in M. Mastalerz, M. Glikson, and S.D. Golding, eds., Coalbed methane: scientific, environmental and economic evaluation: Boston, Kluwer Academic Publishers, p. 297-303.

EPA, 2002, Inventory of U.S. greenhouse gas emissions and sinks: 1990-2000: EPA 430-R-02-003. http://yosemite.epa.gov/oar/globalwarming.nsf/content/ResourceCenterPublicationsGHGEmissionsUSEmissionsInventory2002.html

Ercegovac, M., A. Kostic, H. Karg, D.H. Welte, and R. Littke, 2003, Temperature and burial history modeling of the Drmno and Markovac depressions, SE Pannonian Basin, Serbia: Journal of Petroleum Geology, v. 26, p. 5-27.Ercegovac, M., and A. Kostić, 2006, Organic facies and palynofacies: nomenclature, classification and applicability for petroleum source rock evaluation: International Journal of Coal Geology, v. 68, p. 70-78.

Ertunç, G., A.E. Tercan, M.A. Hindistan, B. Űnver, S. Űnal, F. Atalay, and S.Y. Killioğlu, 2013, Geostatistical estimation of coal quality variables by using covariance matching constrained kriging: International Journal of Coal Geology, v. 112, p. 14-25.Eseme, E., R. Littke, and B.M. Krooss, 2006, Factors controlling the thermo-mechanical deformation of oil shales: implications for compaction of mudstones and exploitation: Marine and Petroleum Geology, v. 23, p. 715-734.Eskanazy, G., R.B. Finkelman, and S. Chattarjee, 2010, Some considerations concerning the use of correlation coefficients and cluster analysis in interpreting coal geochemistry data: International Journal of Coal Geology, v. 83, p. 491-493.Eskenazy, G., D. Delibaltova, and E. Mincheva, 1994, Geochemistry of boron in Bulgarian coals: International Journal of Coal Geology, v. 25, p. 93-110.Eskenazy, G.M., 1995, Geochemistry of arsenic and antimony in Bulgarian coals: Chemical Geology, v. 119, p. 239-254.Eskenazy, G.M., 1999, Aspects of the geochemistry of rare earth elements in coal: an experimental approach: International Journal of Coal Geology, v. 38, p. 285-295.Eskenazy, G.M., 2006, Geochemistry of beryllium in Bulgarian coals: International Journal of Coal Geology, v. 66, p. 305-315.Eskenazy, G.M., 2009, Trace elements geochemistry of the Dobrudza coal basin, Bulgaria: International Journal of Coal Geology, v. 78, p. 192-200.Eskenazy, G.M., and D. Velichkov, 2012, Radium in Bulgarian coals: International Journal of Coal Geology, v. 94, p. 296-301.Eskenazy, G.M., and Y.S. Stefanova, 2007, Trace elements in the Goze Delchev coal deposit, Bulgaria: International Journal of Coal Geology, v. 72, p. 257-267.

Espitalie, J., F. Marquis, E. Lafargue, and R. Antonas, 1996, Improve exploration success using new source rock analyzer: World Oil, v. 217, no. 4, p. 111-112.Espitalie, J., J.L. Laporte, M. Madec, F. Marquis, P. Leplat, J. Paulet, and A. Boutefeu, 1977, Methode rapide de caracterisation des roches meres de leur potentiel petrolier et de leur degre d’evolution: Revue de l’Institute Francais du Petrole, v. 32, p. 23-42.Espitalie, J., K.S. Makadi, and J. Trichet, 1984, Role of the mineral matrix during kerogen pyrolysis: Organic Geochemistry, v. 6, p. 365-382.Espitalie, J., M. Madec, and B. Tissot, 1980, Role of mineral matrix in kerogen pyrolysis: influence on petroleum generation and migration: AAPG Bulletin, v. 64, p. 59-66.

Esterle, J.S., and J.C. Ferm, 1986, Relationship between petrographic and chemical properties and coal seam geometry. Hance seam, Breathitt Formation, southeastern Kentucky: International Journal of Coal Geology, v. 6, p. 204-214.Esterle, J.S., and J.C. Ferm, 1994, Spatial variability in modern tropical peat deposits from Sarawak, Malaysia and Sumatra: International Journal of Coal Geology, v. 26, p. 1-41.Esterle, J.S., J.C. Ferm, and Y.-L. Tie, 1989, A test for the analogy of tropical domed peat deposits to "dulling-up" sequences in coal beds—preliminary results: Organic Geochemistry, v. 14, p. 333-342.Esterle, J.S., T.A. Moore, and J.C. Hower, 1991, A reflected-light petrographic technique for peats: Journal of Sedimentary Petrology, v. 61, p. 614-616.Esterle, J.S., T.A. Moore, and J.C. Hower, 1991, A reflected-light petrographic technique for peats: Journal of Sedimentary Petrology, v. 61, p. 614-616.Ettinger, I., I. Eremin, B. Zimakov, and M. Yanovskaya, 1966, Natural factors influencing coal sorption properties: I. Petrography and sorption properties of coals: Fuel, v. 45, p. 267-275.Ettinger, I., I. Eremin, B. Zimakov, and M. Yanovskaya, 1967, Natural factors influencing coal sorption properties: II. Gas capacity of coals found in weathering zone of coal deposits: Fuel, v. 45, p. 277-282.Ettinger, I., I. Eremin, B. Zimakov, and M. Yanovskaya, 1967, Natural factors influencing coal sorption properties: II. Gas capacity of coals found in weathering zone of coal deposits: Fuel, v. 45, p. 277-282.Ettinger, I., I.L. Lidin, A.M. Dmitriev, and E.S. Zhupakhina, 1958, Systematic handbook for the determination of methane content of coal seams from the seam pressure of the gas and the methane capacity of the coal: Institute of Mining, Academy of Sciences, USSR, USBM Translation No. 1505.Evans, W.D., and D.H. Amos, 1961, An example of the origin of coal balls: Proceedings of the Geologists’ Association, v. 72, p. 445-454.Everson, R.C., H.W.J.P. Neomagus, R. Kaitano, R. Falcon, C. van Alphen, and V.M. du Cann, 2008, Properties of high ash char particles derived from inertinite-rich coal: 1. Chemical, structural and petrographic characteristics: Fuel, v. 87, p. 3082-3090.Everson, R.C., H.W.J.P. Neomagus, R. Kaitano, R. Falcon, C. van Alphen, and V.M. du Cann, 2008, Properties of high ash char particles derived from inertinite-rich coal: 1. Chemical, structural and petrographic characteristics: Fuel, v. 87, p. 3082-3090.Everson, R.C., H.W.J.P. Neomagus, R. Kaitano, R. Falcon, C. van Alphen, and V.M. du Cann, 2008, Properties of high ash char particles derived from inertinite-rich coal: 1. Chemical, structural and petrographic characteristics: Fuel, v. 87, p. 3082-3090.Everson, R.C., H.W.J.P. Neomagus, R. Kaitano, R. Falcon, C. van Alphen, and V.M. du Cann, 2008, Properties of high ash char particles derived from inertinite-rich coal: 1. Chemical, structural and petrographic characteristics: Fuel, v. 87, p. 3082-3090.Fabiańska, M.J., and S. Kurkiewicz, 2013, Biomarkers, aromatic hydrocarbons and polar compounds in the Neogene lignites and gangue sediments of the Konin and Turoszów brown coal basins (Poland): International Journal of Coal Geology, v. 107, p. 24-44.Fabiańska, M.J., J. Ciesielczuk, Ł. Kruszewski, M. Misz-Kennan, D.R. Blake, G. Stracher, and I. Moszumańska, 2013, Gaseous compounds and effluorescences generated in self-heating coal-waste dumps—A case study from the Upper and Lower Silesian coal basins (Poland): International Journal of Coal Geology, v. 116-117, p. 247-261.Fabiańska, M.J., S.R. Ćmiel, and M. Misz-Kennan, 2013, Biomarkers and aromatic hydrocarbons in bituminous coals of Upper Silesian coal basin: Examples from 405 coal seam of the Zaleskie Beds (Poland): International Journal of Coal Geology, v. 107, p. 96-111.

EPA, 2004, Evaluation of impacts to underground sources of drinking water by hydraulic fracturing of coalbed methane reservoirs: U.S. Environmental Protection Agency, EPA 816-R-04-003, 29 p. (http://www.epa.gov/safewater/uic/cbmstudy/docs.html)EPA, 2005, Global coal mine methane utilization: promising opportunities: U.S. Environmental Protection Agency, Coalbed Methane Extra, June 2005, EPA-430-N-00-004, p. 1-7. (http://www.epa.gov/coalbed)EPA, 2005, Global coal mine methane utilization: promising opportunities: U.S. Environmental Protection Agency, Coalbed Methane Extra, June 2005, EPA-430-N-00-004, p. 1-7. (http://www.epa.gov/coalbed)

Ergun, S., 1979, Coal classification and characterization, in C.Y. Wen and E.S. Lee, eds., Coal conversion technology: Reading, Massachusetts, Addison-Wesley Publishing Company, p. 1-56.Ertekin, T., W. Sung, and H.I. Bilgesu, 1991, Structural properties of coal that control coalbed methane production, in D.C. Peters, ed., Geology in coal resource utilization: Fairfax, VA, Techbooks, p. 105-124.

Espitalie, J., 1986, Use of Tmax as a maturation index for different types of organic matter. Comparison with vitrinite reflectance in J. Burrus, ed., Thermal modeling in sedimentary basins: Paris, Editions Technip, p. 475-496.

Essenhigh, R.H., 1981, Fundamentals of coal combustion, in M.A. Elliot, ed., Chemistry of coal utilization, 2nd Supplementary Volume: New York, John Wiley and Sons, p. 1153-1312.Esser, R., R. Levey, B. McPherson, W. O’Dowd, J. Litynski, and S. Plasynski, 2010, Preparing for a carbon constrained world; overview of the United States regional carbon sequestration partnerships programme and its Southwest Regional Partnership, in B.A. Vining and S.C. Pickering, eds., Petroleum geology: from mature basins to new frontiers: London, Geological Society, Proceedings of the 7 th Petroleum Geology Conference, p. 1189-1195.

Fair-Page, T., and A.D. Cohen, 1990, Paleoecological history of west-central Okefenokee swamp based on palynologic and petrographic analysis: Palynology, v. 14, p. 27-39.Faiz, M., A. Saghafi, N. Sherwood, and I. Wang, 2007, The influence of petrological properties and burial history on coal seam methane reservoir characterization, Sydney Basin, Australia: International Journal of Coal Geology, v. 70, p. 193-208.Faiz, M., and P. Hendry, 2006, Significance of microbial activity in Australian coal bed methane reservoirs—a review: Bulletin of Canadian Petroleum Geology, v. 54, p. 261-272.Faiz, M., and P. Henry, 2007, Significance of microbial activity in Australian coal bed methane reservoirs: a review: Bulletin of Canadian Petroleum Geology, v. 54, p. 261-272.Faiz, M., L. Stalker, N. Sherwood, A. Saghafi, M. Wold, S. Barclay, J. Choudhurry, W. Barker, and I. Wang, 2003, Bio-enhancement of coal bed methane resources in the southern Sydney Basin: APPEA Journal, v. 43, part 1, p. 595-610.Faiz, M.M., 1993, Geological controls on the distribution of coal seam gases in the southern Sydney Basin: University of Wollongong, unpublished PhD thesis, 326 p.

Falcon, R.M.S., and C.P. Snyman, 1986, An introduction to coal petrography: atlas of petrographic constituents in the bituminous coals of southern Africa: Geological Society of South Africa Review Paper 2, 27 p. + 39 plates.Falcon, R.M.S., and C.P. Snyman, 1986, An introduction to coal petrography: atlas of petrographic constituents in the bituminous coals of southern Africa: The Geological Society of South Africa, Review Paper No. 2, 108 p.

Falcon-Lang, H.J., 1999, Fire ecology of a late Carboniferous floodplain, Joggins, Nova Scotia: London, Journal of the Geological Society, v. 156, p. 137-148.Falcon-Lang, H.J., 2000, Fire ecology of the Carboniferous tropical zone: Palaeogeogrpahy, Palaeoclimatology, Palaeoecology, v. 164, p. 339-355.Falcon-Lang, H.J., 2004, Pennsylvanian tropical rain forests responded to glacial-interglacial rhythms: Geology, v. 32, p. 689-692.Falcon-Lang, H.J., C.J. Cleal, J.L. Pendleton, and C.H. Wellman, 2012, Pennsylvanian (mid/late Bolsovian-Asturian) permineralized plant assemblages of the Pennant Sandstone Formation of southern Britain: Systematics and palaeoecology: Review of Palaeobotany and Palynology, v. 173, p. 23-45.Falivene, O., L. Cabrera, and A. Sáez, 2007, Optimum and robust 3D facies interpolation strategies in a heterogeneous coal zone (Tertiary As Pontes Basin, NW Spain): International Journal of Coal Geology, v. 71, p. 185-208.Falivene, O., L. Cabrera, and A. Sáez, 2014, Forecasting coal resources and reserves in heterogeneous coal zones using 3D facies models (As Pontes Basin, NW Spain): International Journal of Coal Geology, v. 130, p. 8-26.Fallgren, P.H., C. Zeng, Z. Ren, A. Lu, S. Ren, and S. Jin, 2013, Feasibility of microbial production of new natural gas from non-gas-producing lignite: International Journal of Coal Geology, v. 115, p. 79-84.Fallgren, P.H., S. Jin, C. Zeng, A. Lu, and P.J.S. Colberg, 2013, Comparison of coal rank for enhanced biogenic natural gas production: International Journal of Coal Geology, v. 115, p. 92-96.Fan, J., K. Liu, Y. Ju, S. Liu, and L. Gui, 2012, Total scanning fluorescence characteristics of coals and implication to coal rank evaluation: Journal of Geological Research, v. 2012, 6 p.Fan, J., Y. Ju, Q. Hou, Y. Wu, and X. Li, 2012, Characterization of coal reservoirs in two major coal fields in northern China: Implications for coalbed methane development: Journal of Geological Research, v. 2012, 10 p.Fang, H., and C. Jianyu, 1992, The cause and mechanism of vitrinite reflectance anomalies: Journal of Petroleum Geology, v. 15, p. 419-434.Faraj, B., A. Hatch, D. Krivak, and P. Smolarchuk, 2004, Mechanism of hydrogen generation in coalbed methane desorption canisters: causes and remedies: GasTIPS, v. 10, no. 2, p. 15-19.Faraj, B.S.M., and I.D.R. Mackinnon, 1993, Micrinite in southern hemisphere sub-bituminous and bituminous coals: redefined as fine grained kaolinite: Organic Geochemistry, v. 20, p. 823-841.Faraj, B.S.M., C.R. Fielding, and I.D.R. MacKinnon, 1996, Cleat mineralization of Upper Permian Baralaba/Rangal coal measures, Bowen Basin, Australia: Geological Society of London, Special Publication 109, p. 151-164.Farhaduzzaman, M., W.H. Abdullah, and M.A. Islam, 2012, Depositional environment and hydrocarbon source potential of the Permian Gondwana coals from the Barapukuria Basin, northwest Bangladesh: International Journal of Coal Geology, v. 90-91, p. 162-179.Farhaduzzaman, M., W.H. Abdullah, and M.A. Islam, 2012, Depositional environment and hydrocarbon source potential of the Permian Gondwana coals from the Barapukuria Basin, northwest Bangladesh: International Journal of Coal Geology, v. 90-91, p. 162-179.Fassett, J.E., 1987, Geometry and depositional environments of Fruitland Formation coalbeds, San Juan basin, New Mexico and Colorado: anatomy of a giant coal-bed methane deposit: Tuscaloosa, Alabama, Proceedings of the 1987 Coalbed Methane Symposium, paper 8712, p. 19-35.

Fassett, J.E., ed., 1988, Geology and coal-bed methane resources of the northern San Juan basin, Colorado and New Mexico: Denver, Rocky Mountain Association of Geologists Guidebook, 351 p.Fathi, E., and I.Y. Akkutlu, 2008, Counter-diffusion and competitive adsorption effects during CO2 injection and coalbed methane production: SPE paper 115482, 15 p.Fathi, E., and I.Y. Akkutlu, 2008, Counter-diffusion and competitive adsorption effects during CO2 injection and coalbed methane production: SPE Paper 115482, 15 p.Fathi, E., and I.Y. Akkutlu, 2009, Matrix heterogeneity effects on gas transport and adsorption in coalbed and shale gas reservoirs: Transport in Porous Media, v. 80, p. 281-304.Fathi, E., and I.Y. Akkutlu, 2014, Multi-component gas transport and adsorption effects during CO2 injection and enhanced shale gas recovery: International Journal of Coal Geology, v. 123, p. 52-61.Fatimah, and C.R. Ward, 2009, Mineralogy and organic petrology of oil shales in the Sangkarewang Formation, Ombilin Basin, west Sumatra, Indonesia: International Journal of Coal Geology, v. 77, p. 424-435.Faure, P., P. Landais, and L. Griffault, 1999, Behavior of organic matter from Callovian shales during low-temperature air oxidation: Fuel, v. 78, p. 1515-1525.Fedor, F., and M. Hámor-Vidó, 2003, Statistical analysis of vitrinite reflectance data—a new approach: International Journal of Coal Geology, v. 56, p. 277-294.Fedor, F., and M. Hámor-Vidó, 2003, Statistical analysis of vitrinite reflectance data—a new approach: International Journal of Coal Geology, v. 56, p. 277-294.Fei, Y., M. Marshall, W.R. Jackson, M.L. Gorbaty, M.W. Amer, P.J. Cassidy, and A.L. Chaffee, 2012, Evaluation of several methods of extraction of oil from a Jordanian oil shale: Fuel, v. 92, p. 281-287.Feldmann, R.M., R.E. Chapman, and J.T. Hannibal, eds., 1989, Paleotechniques: The Paleontological Society Special Publication 4, 358 p.

Faiz, M.M., A. Saghafi, and N. Sherwood, 1999, Higher hydrocarbon gases in southern Sydney Basin coals, in M. Mastalerz, M. Glikson, and S.D. Golding, eds., Coalbed methane: scientific, environmental and economic evaluation: Boston, Kluwer Academic Publishers, p. 233-255.

Falcone, S.K., and H.H. Schobert, 1984, Mineral transformations during ashing of selected low-rank coals, in K.S. Vorres, ed., Mineral matter and ash in coal: American Chemical Society Symposium Series 301, p. 114-127.Falcone, S.K., and H.H. Schobert, 1984, Mineral transformations during ashing of selected low-rank coals, in K.S. Vorres, ed., Mineral matter and ash in coal: American Chemical Society Symposium Series 301, p. 114-127.

Fassett, J.E., 1989, Coal-bed methane - a contumacious, free-spirited bridge; the geologic handmaiden of coal beds, in J.C. Lorenz and S.G. Lucas, eds., Energy frontiers in the Rockies: Albuquerque Geological Society, p. 131-146.Fassett, J.E., and B.C. Boyce, 2005, Fractured-sandstone gas reservoirs, San Juan Basin, New Mexico and Colorado: With an overview of Fruitland Formation coal-bed methane, in M.G. Bishop, S.P. Cumella, J.W. Robinson, and M.R. Silverman, eds., Gas in low-permeability reservoirs of the Rocky Mountain region: Rocky Mountain Association of Geologists 2005 Guidebook, p. 109-185.

Felgueroso, J., A. Martinez-Alonso, M.R. Martinez-Tarazona, and J.M.D. Tascon, 1988, The determination of mineral matter content of low-rank coals: Journal of Coal Quality, v. 7, p. 127-131.Felix, C., and P. Burbridge, 1986, Variables to be considered in kerogen microscopy: The Texas Journal of Science, v. 38, p. 139-145.Felix, C., and P. Burbridge, 1986, Variables to be considered in kerogen microscopy: The Texas Journal of Science, v. 38, p. 139-145.Feng, J., 1988, Coal combustion: science and technology of industrial and utility applications: New York, Hemisphere Publications Corp., 1014 p.Feng, Q., J. Zhang, X. Zhang, and A. Hu, 2012, Optimizing well placement in a coalbed methane reservoir using the particle swarm optimization algorithm: International Journal of Coal Geology, v. 104, p. 34-45.Feng, Q., J. Zhang, X. Zhang, C. Shu, S. Wen, S. Wang, and J. Li, 2014, The use of alternating conditional expectation to predict methane sorption capacity on coal: International Journal of Coal Geology, v. 121, p. 137-147.Feng, X., and Y. Hong, 1999, Modes of occurrence of mercury in coals from Guizhou, People’s Republic of China: Fuel, v. 78, p. 1181-1188.Fensky, C., and M. Yakimov, 2013, Improving evaluation efficiency in CBM formations: Hart Energy Publishing, E&P, v. 86, no. 4, p. 70, 72.Ferguson, D.K., D.E. Lee, J.M. Bannister, R. Zetter, G.J. Jordan, N. Vavra, and D.C. Mildenhall, 2010, The taphonomy of a remarkable leaf bed assemblage from the Late Oligocene-Early Miocene Gore lignite measures, southern New Zealand: International Journal of Coal Geology, v. 83, p. 173-181.Ferm, J.C., 1925-1999, List of publications and special issue: International Journal of Coal Geology, v. 49, p. 67-214.

Ferm, J.C., and G.A. Weisenfluh, 1989, Evolution of some depositional models in late Carboniferous rocks of the Appalachian coal fields: International Journal of Coal Geology, v. 12, p. 259-292.

Ferm, J.C., J.C. Horne, G.A. Weisenfluh, R.C. Milici, and J.R. Staub, eds., 1979, Carboniferous depositional environments in the Appalachian region: Columbia, University of South Carolina, Carolina Coal Group, 760 p.Fermont, W.J.J., 1988, Possible causes of abnormal vitrinite reflectance values in paralic deposits of the Carboniferous in the Achterhoek area, The Netherlands: Organic Geochemistry, v. 12, p. 401-411.Fermont, W.J.J., 1988, Possible causes of abnormal vitrinite reflectance values in paralic deposits of the Carboniferous in the Achterhoek area, The Netherlands: Organic Geochemistry, v. 12, p. 401-411.Ferraro, M., J. Gelli, and R. Damiani, 1994, An application of petrographic analyses on the combustion of coal (abstract): ICCP News, no. 10, p. 8-9.Fessenden, J., 2012, Carbon sequestration and natural analogs: Geology, v. 40, p. 575-576.Field, T. W., 2004, Surface to in-seam drilling – the Australian experience: Tuscaloosa, Alabama, University of Alabama, College of Continuing Studies, 2004 International Coalbed Methane Symposium Proceedings, paper 0408, 10 p.Fielding, C.R., 1987, Coal depositional models for deltaic and alluvial plain sequences: Geology, v. 15, p. 661-664. (comment and reply, v. 16, p. 284-285)Fielding, C.R., and M. Glikson, 1992, Hydrous vitrinite as a liquid hydrocarbon source in Permian and Mesozoic eastern Australian coal (abstract): AAPG Bulletin, v. 76, p. 1101-1102.Fields, H.H., J.H. Perry, and M. Deul, 1975, Commercial-quality gas from a multipurpose borehole located in the Pittsburgh coalbed: U.S. Bureau of Mines, Report of Investigations 8025, 14 p.Figueiredo, J.L., and J.A. Moulijn, eds., 1986, Carbon and coal gasification: Boston, Martinus Nijhoff Publishers, NATO ASI Series E, Applied Sciences No. 105, 655 p.Filho, J.G.M., 2008, Report on organic matter concentration working group (OMCWG 2008): ICCP News, no. 45, p. 43-51.Filippidis, A., A. Georgakopoulos, and A. Kassoli-Fournaraki, 1996, Mineralogical components of some thermally decomposed lignite and lignite ash from the Ptolemais basin, Greece: International Journal of Coal Geology, v. 30, p. 303-314.Findley, M., and K. Shirley, 2006, Options for CBM production: Hart Energy Publishing, E&P, v. 79, no. 1, p. 70, 72, 74.

Finkelman, R.B., 1989, What we don’t know about the occurrence and distribution of the trace elements in coal: Journal of Coal Quality, v. 8, p. 63-66.Finkelman, R.B., 1993, The use of modes of occurrence information to predict the removal of the hazardous air pollutants prior to combustion: Journal of Coal Quality, v. 12, no. 4, p. 132-134.Finkelman, R.B., 1993, The use of modes of occurrence information to predict the removal of the hazardous air pollutants prior to combustion: Journal of Coal Quality, v. 12, p. 132-134.

Finkelman, R.B., 1994, Modes of occurrence of potentially hazardous elements in coal: levels of confidence: Fuel Processing Technology, v. 39, p. 21-24.Finkelman, R.B., 1994, Modes of occurrence of potentially hazardous elements in coal: levels of confidence: Fuel Processing Technology, v. 39, p. 21-34.Finkelman, R.B., 1995, Environmental impacts of coal utilization phase I. Characterization of solid waste products — a team approach: TSOP Newsletter, v. 12, no. 1, p. 8-9.Finkelman, R.B., 1998, "Air toxics" from coal combustion: implications for global fossil fuel use (abstract): TSOP Abstracts and Program, v. 15, p. 6-8.

Finkelman, R.B., 2004, Potential health impacts of burning coal beds and waste banks: International Journal of Coal Geology, v. 59, p. 19-24.Finkelman, R.B., and B.J. Cardott, 1993, Trace-element content of solid hydrocarbons from Oklahoma: Oklahoma Geological Survey, Oklahoma Geology Notes, v. 53, p. 136-143.Finkelman, R.B., and P.M.K. Gross, 1999, The types of data needed for assessing the environmental and human health impacts of coal: International Journal of Coal Geology, v. 40, p. 91-101.

Ferm, J.C., 1974, Carboniferous environmental models in eastern United States and their significance, in G. Briggs, ed., Carboniferous of the southeastern United States: Geological Society of America Special Paper 148, p. 79-95.Ferm, J.C., 1984, Geology of coal, in C.R. Ward, ed., Coal geology and coal technology: Blackwell Scientific Publications, p. 151-176.

Ferm, J.C., and J.R. Staub, 1984, Depositional controls of mineable coal bodies, in R.A. Rahmani and R.M. Flores, eds., Sedimentology of coal and coal-bearing sequences: Boston, Blackwell Scientific Publications, International Association of Sedimentologists, Special Publication 7, p. 275-289.

Finkelman, R.B., 1982, Modes of occurrence of trace elements and minerals in coal: an analytic approach, in R.H. Filby, B.S. Carpenter, and R.C. Ragaini, eds., Atomic and nuclear methods in fossil energy research: New York, Plenum Press, p. 141-149.

Finkelman, R.B., 1993, Trace and minor elements in coal, in M.H. Engel and S.A. Macko, eds., Organic geochemistry: New York, Plenum Press, p. 593-607.

Finkelman, R.B., 2003, Mercury in coal and mercury emissions from coal combustion, in J.E. Gray, ed., Geologic studies of mercury by the U.S. Geological Survey: U.S. Geological Survey Circular 1248, p. 9-11.

Finkelman, R.B., and S.J. Tewalt, 1998, Mercury in U.S. coal: U.S. Geological Survey Open-File Report OF98-0772. (http://pubs.usgs.gov/of/1998/of98-772/)

Finkelman, R.B., F.L. Fiene, R.N. Miller, and F.O. Simon, eds., 1984, Interlaboratory comparison of mineral constituents in a sample from the Herrin (no. 6) coal bed from Illinois: USGS Circular 932, 42 p.Finkelman, R.B., N.H. Bostick, F.T. Dulong, F.E. Senftle, and A.N. Thorpe, 1998, Influence of an igneous intrusion on the inorganic geochemistry of a bituminous coal from Pitkin County, Colorado: International Journal of Coal Geology, v. 36, p. 223-241.Finkelman, R.B., W. Orem, V. Castranova, C.A. Tatu, H.E. Belkin, B. Zheng, H.E. Lerch, S.V. Maharaj, and A.L. Bates, 2002, Health impacts of coal and coal use: possible solutions: International Journal of Coal Geology, v. 50, p. 425-443.Firouzi, M., E.C. Rupp, C.W. Liu, and J. Wilcox, 2014, Molecular simulation and experimental characterization of the nanoporous structures of coal and gas shale: International Journal of Coal Geology, v. 121, p. 123-128.Firouzi, M., E.C. Rupp, C.W. Liu, and J. Wilcox, 2014, Molecular simulation and experimental characterization of the nanoporous structures of coal and gas shale: International Journal of Coal Geology, v. 121, p. 123-128.Fischer, C., and R. Gaupp, 2005, Change of black shale organic material surface area during oxidative weathering: implications for rock-water surface evolution: Geochimica et Cosmochimica Acta, v. 69, p. 1213-1224.Fischer, C., V. Karius, and V. Thiel, 2007, Organic matter in black slate shows oxidative degradation within only a few decades: Journal of Sedimentary Research, v. 77, p. 355-365.Fischer, P.A., 2005, Hopes for shale oil are revived: World Oil, v. 226, no. 8, p. 69-74.Fischer, P.A., 2008, Shale oil pilot projects proliferate: World Oil, v. 229, no. 8.Fisher, C.H., G.C. Sprunk, A. Eisner, H.J. O’Donnell, L. Clarke, and H.H. Storch, 1942, Hydrogenation and liquefaction of coal, part 2—effect of petrographic composition and rank of coal: U.S. Bureau of Mines, Technical Paper 642, 162 p.Fisher, J., 2005, CBM is the place to be: Supplement to Oil and Gas Investor, v. 25, no. 12, p. 2-7.Fisher, J., 2005, CBM technology on the rise: Supplement to Oil and Gas Investor, v. 25, no. 12, p. 8-13.Fisk, J.C., 2010, Correlating deliverability to seismic attributes in coalbed-methane exploitation: Norman, Oklahoma, University of Oklahoma, unpublished M.S. thesis, 69 p.Fitzgerald, J.E., Z. Pan, M. Sudibandriyo, R.L. Robinson, Jr., K.A.M. Gasem, and S. Reeves, 2005, Adsorption of methane, nitrogen, carbon dioxide and their mixtures on wet Tiffany coal: Fuel, v. 84, p. 2351-2363.

Fleck, S., R. Michels, A. Izart, M. Elie, and P. Landais, 2001, Palaeoenvironmental assessment of Westphalian fluvio-lacustrine deposits of Lorraine (France) using a combination of organic geochemistry and sedimentology: International Journal of Coal Geology, v. 48, p. 65-88.

Fletcher, S., 2005, Industry, US government take new look at oil shale: Oil & Gas Journal, v. 103.15, p. 26-28. (April 18, 2005)

Flores, R.M., 1989, Depositional systems and their peat/coal forming environments: U.S. Geological Survey Open File Report OF 88-0406, 115 p.

Flores, R.M., 2004, Coalbed methane in the Powder River Basin, Wyoming and Montana: an assessment of the Tertiary-Upper Cretaceous coalbed methane total petroleum system: U.S. Geological Survey, Digital Data Series, DDS-69-c, chapter 2.Flores, R.M., 2013, Coal and coalbed gas, fueling the future: Elsevier Science, 717 p.Flores, R.M., 2013, Coal and coalbed gas, fueling the future: Elsevier Science, 717 p.Flores, R.M., B.D. Spear, S.A. Kinney, P.A. Purchase, and C.M. Gallagher, 2010, After a century—Revised Paleogene coal stratigraphy, correlation, and deposition, Powder River Basin, Wyoming and Montana: U.S. Geological Survey Professional Paper 1777, 97 p.Flores, R.M., B.D. Spear, S.A. Kinney, P.A. Purchase, and C.M. Gallagher, 2010, After a century—Revised Paleogene coal stratigraphy, correlation, and deposition, Powder River Basin, Wyoming and Montana: U.S. Geological Survey Professional Paper 1777, 97 p.Flores, R.M., C.A. Rice, G.D. Stricker, A. Warden, and M.S. Ellis, 2008, Methanogenic pathways of coal-bed gas in the Powder River Bsain, United States: The geologic factor: International Journal of Coal Geology, v. 76, p. 52-75.

Flores, R.M., G.D. Stricker, and S.A. Kinney, 2004, Alaska coal geology, resources, and coalbed methane potential: U.S. Geological Survey Digital Data Series DDS-77, CD-ROM.Flores, R.M., L.F. Blanchard, J.D. Sanchez, W.E. Marley, and W.J. Muldoon, 1984, Paleogeographic controls of coal accumulation, Cretaceous Blackhawk Formation and Star Point Sandstone, Wasatch Plateau, Utah: Geological Society of America Bulletin, v. 95, p. 540-550.Fokker, P.A. and L.G.H. Van der Meer, 2004, The injectivity of coalbed CO2 injection wells: Energy, v. 29, p. 1423-1429.Foner, H.A., T.L. Robl, J.C. Hower, and U.M. Graham, 1999, Characterization of fly ash from Israel with reference to its possible utilization: Fuel, v. 78, p. 215-223.Forgotson, J.M., and S.A. Friedman, 1993, Arkoma basin (Oklahoma) coal-bed methane resource base and development (abstract): AAPG Annual Convention Official Program, p. 103.Formolo, M., A. Martini, and S. Petsch, 2008, Biodegradation of sedimentary organic matter associated with coalbed methane in the Powder River and San Juan basins, U.S.A.: International Journal of Coal Geology, v. 76, p. 86-97.

Förster, A., R. Schöner, H.-J. Förster, B. Norden, A.-W. Blaschke, J. Luckert, G. Beutler, and R. Gaupp, 2010, Reservoir characterization of a CO2 storage aquifer: the Upper Triassic Stuttgart Formation in the Northeast German Basin: Marine and Petroleum Geology, v. 27, p. 2156-2172.Forsythe, R.F., D. Li, and J.T. Riley, 1994, An improved method for the determination of sulfur in coal ash: Journal of Coal Quality, v. 13, p. 118-122.

Flaviano, C., F. Le Berre, S. Derenne, C. Largeau, and J. Connan, 1994, First indications of the formation of kerogen amorphous fractions by selective preservation. Role of non-hydrolysable macromolecular constituents of Eubacterial cell walls, in N. Telnaes, and others, eds., Advances in organic geochemistry 1993: Organic Geochemistry, v. 22, p. 759-771.

Fleet, A.J., and A.C. Scott, 1994, Coal and coal-bearing strata as oil-prone source rocks: an overview, in A.C. Scott and A.J. Fleet, eds., Coal and coal-bearing strata as oil-prone source rocks?: London, The Geological Society Special Publication 77, p. 1-8.

Flores, R.M., 1980, Comparison of depositional models of Tertiary and Upper Cretaceous coal-bearing rocks in some Western Interior basins of the United States, in L.M. Carter, ed., Proceedings of the fourth symposium on the geology of Rocky Mountain coal–1980: Colorado Geological Survey Resource Series 10, p. 17-20.

Flores, R.M., 1993, Coal-bed and related depositional environments in methane gas-producing sequences, in B.E. Law and D.D. Rice, eds., Hydrocarbons from coal: AAPG Studies in Geology 38, p. 13-37.Flores, R.M., 1993, Coal-bed and related depositional environments in methane gas-producing sequences, in B.E. Law and D.D. Rice, eds., Hydrocarbons from coal: AAPG Studies in Geology 38, p. 13-37.Flores, R.M., 1998, Coalbed methane: from hazard to resource, in R.M. Flores, ed., Coalbed methane: from coal-mine outbursts to a gas resource: International Journal of Coal Geology, v. 35, p. 3-26.Flores, R.M., 2004, Coal buildup in tide-influenced coastal plains in the Eocene Kapuni Group, Taranaki Basin, New Zealand, in J.C. Pashin and R.A. Gastaldo, eds., Sequence stratigraphy, paleoclimate, and tectonics of coal-bearing strata: AAPG Studies in Geology 51, p. 45-70.

Flores, R.M., G.D. Stricker, and S.A. Kinney, 2003, Alaska coal resources and coalbed methane potential: U.S. Geological Survey Bulletin 2198, 4 p. http://pubs.usgs.gov/bul/b2198/

Forrest, M., and H. Marsh, 1982, Theoretical and experimental approaches to the carbonization of coal and coal blends, in E.L. Fuller, Jr., ed., Coal and coal products: Analytical characterization techniques: American Chemical Society, ACS Symposium Series 205, p. 1-25.Forsberg, A., and M. Bjorøy, 1983, A sedimentological and organic geochemical study of the Botneheia Formation, Svalbard, with special emphasis on the effects of weathering on the organic matter in shales, in M. Bjorøy et al., eds., Advances in organic geochemistry 1981: New York, John Wiley & Sons, p. 60-68.

Fouch, T.D., V.F. Nuccio, and T.C. Chidsey, Jr., eds., 1992, Hydrocarbon and mineral resources of the Uinta basin, Utah and Colorado: Salt Lake City, Utah Geological Association, Guidebook 20, 366 p.

Frailey, S.M., R.J. Finley, and J.A. Rupp, 2013, Illinois Basin, Midwest carbon dioxide EOR challenges may be surmountable: Oil & Gas Journal, v. 111.1, p. 64-73.Frailey, S.M., R.J. Finley, and T.S. Hickman, 2006, CO2 sequestration: storage capacity guideline needed: Oil & Gas Journal, v. 104.30, p. 44-46, 48-49.Francis, W., 1954, Coal, its formation and composition: London, Edward Arnold (Publishers) Ltd., 567 p.Frank, M.C., and R.V. Tyson, 1995, Parasequence-scale organic facies variations through an early Carboniferous Yoredale cyclothem, Middle Limestone Group, Scremerston, Northumberland: Journal of the Geological Society, London, v. 152, part 1, p. 41-50.Frankie, K.A., and J.C. Hower, 1987, Variation in pyrite size, form and microlithotype association in the Springfield (no. 9) and Herrin (no. 11) coals, western Kentucky: International Journal of Coal Geology, v. 7, p. 349-364.Fredericks, P.M., P. Warbrooke, and M.A. Wilson, 1983, Chemical changes during natural oxidation of a high volatile bituminous coal: Organic Geochemistry, v. 5, p. 89-97.

Friedman, S.A., 1967, Stratigraphic analysis of key beds in cyclothems in the Staunton Formation (Middle Pennsylvanian) in the Clinton area, west-central Indiana: Journal of Sedimentary Petrology, v. 37, p. 175-183.

Friedman, S.A., 1982, Determination of reserves of methane from coal beds for use in rural communities in eastern Oklahoma: OGS Special Publication 82-3, 32 p.Friedman, S.A., 1989, Coal-bed methane resources in Arkoma basin, southeastern Oklahoma (abstract): AAPG Bulletin, v. 73, p. 1046.Friedman, S.A., 1991, Fracture and structure of principal coal beds related to coal mining and coalbed methane, Arkoma basin, eastern Oklahoma: AAPG EMD trip 2, AAPG Annual Convention, Dallas, Texas.Friedman, S.A., 1997, Coal-bed methane resources and reserves of Osage County, Oklahoma (abstract): AAPG Bulletin, v. 81, p. 1350.Frodsham, K., and R.A. Gayer, 1999, The impact of tectonic deformation upon coal seams in the South Wales coalfield, UK: International Journal of Coal Geology, v. 38, p. 297-332.Frost, C.D., B.N. Pearson, K.M. Ogle, E.L. Heffern, and R.M. Lyman, 2002, Sr isotope tracing of aquifer interactions in an area of accelerating coal-bed methane production, Powder River Basin, Wyoming: Geology, v. 30, p. 923-926. (water)Frost, C.D., B.N. Pearson, K.M. Ogle, E.L. Heffern, and R.M. Lyman, 2002, Sr isotope tracing of aquifer interactions in an area of accelerating coal-bed methane production, Powder River Basin, Wyoming: Geology, v. 30, p. 923-926. (water)Fu, X., J. Wang, F. Tan, X. Feng, and S. Zeng, 2013, Minerals and potentially hazardous trace elements in the Late Triassic coals from the Qiangtang Basin, China: International Journal of Coal Geology, v. 116-117, p. 93-105.Fu, X., J. Wang, F. Tan, X. Feng, and S. Zeng, 2013, Minerals and potentially hazardous trace elements in the Late Triassic coals from the Qiangtang Basin, China: International Journal of Coal Geology, v. 116-117, p. 93-105.Fu, X., J. Wang, F. Tan, X. Feng, D. Wang, and C. Song, 2012, Geochemistry of terrestrial oil shale from the Lunpola area, northern Tibet, China: International Journal of Coal Geology, v. 102, p. 1-11.Fu, X., J. Wang, Y. Zeng, F. Tan, and X. Feng, 2010, REE geochemistry of marine oil shale from the Changshe Mountain area, northern Tibet, China: International Journal of Coal Geology, v. 81, p. 191-199.Fu, X., J. Wang, Y. Zeng, F. Tan, and X. Feng, 2011, Concentration and mode of occurrence of trace elements in marine oil shale from the Bilong Co area, northern Tibet, China: International Journal of Coal Geology, v. 85, p. 112-122.Fu, X., J. Wang, Y. Zeng, F. Tan, X. Feng, and W. Chen, 2011, Geochemistry of platinum group elements in marine oil shale from the Changshe Mountain area (China): Implications for modes of occurrence and origins: International Journal of Coal Geology, v. 86, p. 169-176.Fu, X., J. Wang, Y. Zeng, Z. Li, and Z. Wang, 2009, Geochemical and palynological investigation of the Shengli River marine oil shale (China): Implications for paleoenvironment and paleoclimate: International Journal of Coal Geology, v. 78, p. 217-224.Fu, X., Y. Qin, G.G.X. Wang, and V. Rudolph, 2009, Evaluation of coal structure and permeability with the aid of geophysical logging technology: Fuel, v. 88, p. 2278-2285.Fu, X., Y. Qin, G.G.X. Wang, and V. Rudolph, 2009, Evaluation of gas content of coalbed methane reservoirs with the aid of geophysical logging technology: Fuel, v. 88, p. 2269-2277.Fujimoto, K.-I., 1990, Mesophase control for pitch cokes production: Erdöl und Kohle-Erdgas-Petrochemie, v. 43, no. 1, p. 34-37.Fujioka, M., S. Yamaguchi, and M. Nako, 2010, CO2-ECBM field tests in the Ishikari coal basin of Japan: International Journal of Coal Geology, v. 82, p. 287-298.Furimsky, E., A.D. Palmer, W.D. Kalkreuth, A.R. Cameron, and G. Kovacik, 1990, Prediction of coal reactivity combustion and gasification by using petrographic data: Fuel Process Technology, v. 25, p. 135-151.Furimsky, E., J.-P. Charland, R. Dureau, W. Kalkreuth, and I. Wieschenkamper, 1991, Use of structural parameters of Canadian coals to follow coalification process: Erdol und Kohle-Erdgas-Petrochemie, v. 44, p. 249-252.Furimsky, E., L. Zheng, F. Boudreau, and G. Kovacik, 1993, Entrained bed gasification of coal. Prediction of contaminant levels using thermodynamic calculations: Erdöl und Kohle-Erdgas-Petrochemie, v. 46, no. 10, p. 379-385.Furmann, A., A. Schimmelmann, S.C. Brassell, M. Mastalerz, and F. Picardal, 2013, Chemical compound classes supporting microbial methanogenesis in coal: Chemical Geology, v. 339, p. 226-241.Furmann, A., M. Mastalerz, S.C. Brassell, A. Schimmelmann, and F. Picardal, 2013, Extractability of biomarkers from high- and low-vitrinite coals and its effect on the porosity of coal: International Journal of Coal Geology, v. 107, p. 141-151.

Gaddy, D.E., 1999, Coalbed methane production shows wide range of variability: Oil & Gas Journal, v. 97, no. 17, p. 41-42.

Gagarin, S.G., and A.A. Krichko, 1992, The petrographic approach to coal liquefaction: Fuel, v. 71, p. 785f

Fowler, M.G., D.M. Kirste, F. Goodarzi, and R.W. Macqueen, 1993, Optical and geochemical classification of Pine Point bitumens and evidence for their origin from two separate source rocks, in F. Goodarzi and R.W. Macqueen, eds., Geochemistry and petrology of bitumen with respect to hydrocarbon generation and mineralization: Energy Sources, v. 15, p. 315-337.Fowler, M.G., F. Goodarzi, T. Gentzis, and P.W. Brooks, 1991, Hydrocarbon potential of Middle and Upper Devonian coals from Melville Island, Arctic Canada, in P.K. Mukhopadhyay, M.G. Fowler, and W.G. Dow, eds., Selected papers from the symposium on coal and terrestrial organic matter as a source rock for petroleum: Organic Geochemistry, v. 17, p. 681-694.Fowler, M.G., L.D. Stasiuk, M. Hearn, and M. Obermajer, 2004, Evidence for Gloeocapsomorpha prisca in Late Devonian source rocks from southern Alberta, Canada: Organic Geochemistry, v. 35, p. 425-441.

Freudenberg, U., S. Lou, R. Schlutz, and K. Thomas, 1996, Main factors controlling coalbed methane distribution in the Ruhr District, Germany, in R. Gayer and I. Harris, eds., Coalbed methane and coal geology: London, Geological Society Special Publication 109, p. 67-88.Friedman, S., P.M. Yavorsky, and S. Akhtar, 1976, Conversion of caking coals to low-sulfur fuel oil in the synthoil process, in C.J. Smith, compiler, Proceedings of the coal agglomeration and conversion symposium: West Virginia Geological and Economic Survey, p. 147-161.

Friedman, S.A., 1978, Field description and characterization of coals sampled by the Oklahoma Geological Survey, 1971–1976, in R.R. Dutcher, ed., Field description of coal: Philadelphia, PA, American Society for Testing and Materials, Special Technical Publication 661, p. 58-63.

Fyfe, W.S., 1999, Clean energy for 10 billion humans in the 21st century: is it possible?: International Journal of Coal Geology, v. 40, p. 85-90.

Gadsden, W.R., and R.G. Wilson, 1981, Evaluation of Australian coals and cokes for large blast furnaces, in Proceedings of the 40th Ironmaking Conference: Iron and Steel Society of AIME, p. 400-407.

Gal, N.L., V. Lagneau, and A. Charmoille, 2012, Experimental characterization of CH4 release from coal at high hydrostatic pressure: International Journal of Coal Geology, v. 96-97, p. 82-92.Gal, N.L., V. Lagneau, and A. Charmoille, 2012, Experimental characterization of CH4 release from coal at high hydrostatic pressure: International Journal of Coal Geology, v. 96-97, p. 82-92.Galeczka, I., D. Wolff-Boenisch, T. Jonsson, B. Sigfusson, A. Stefansson, and S.R. Gislason, 2013, A novel high pressure column flow reactor for experimental studies of CO2 mineral storage: Applied Geochemistry, v. 30, p. 91-104.Gallagher, L.K., A.W. Glossner, L.L. Landkamer, L.A. Figueroa, K.W. Mandernack, and J. Munakata-Marr, 2013, The effect of coal oxidation on methane production and microbial community structure in Powder River Basin coal: International Journal of Coal Geology, v. 115, p. 71-78.Galloway, W. E., and Hobday, D. K., 1996, Terrigenous clastic depositional systems: Application to fossil fuel and groundwater resources, 2nd ed.: New York, Springer, 489 p.Galloway, W.E., and D.K. Hobday, 1996, Terrigenous clastic depositional systems (second completely revised, updated, and enlarged edition): New York, Springer-Verlag, 489 p.

Galtier, J., 1997, Coal-ball floras of the Namurian-Westphalian of Europe: Review of Palaeobotany and Palynology, v. 95, p. 51-72.

Gamson, P.D., B.B. Beamish, and D.P. Johnson, 1993, Coal microstructure and micropermeability and their effects on natural gas recovery: Fuel, v. 72, p. 87-99.Gan, H., S.P. Nandi, and P.L. Walker, Jr., 1972, Nature of porosity in American coals: Fuel, v. 51, p. 272-277.Gan, H., S.P. Nandi, and P.L. Walker, Jr., 1972, Nature of porosity in American coals: Fuel, v. 51, p. 272-277.Gan, H., S.P. Nandi, and P.L. Walker, Jr., 1972, Nature of the porosity in American coals: Fuel, v. 51, p. 272-277.Ganz, H., and W. Kalkreuth, 1990, The potential of infrared spectroscopy for the classification of kerogen, coal and bitumen: Erdol und Kohle - Erdgas - Petrochemie, v. 43, p. 116-117.Gao, L., S.C. Brassell, M. Mastalerz, and A. Schimmelmann, 2013, Microbial degradation of sedimentary organic matter associated with shale gas and coalbed methane in eastern Illinois Basin (Indiana), USA: International Journal of Coal Geology, v. 107, p. 152-164.

Garcia-Gonzalez, M., D.B. MacGowan, and R.C. Surdam, 1993, Coal as a source rock of petroleum and gas - a comparison between natural and artificial maturation of the Almond Formation coals, Greater Green River basin in Wyoming: U.S. Geological Survey Professional Paper 1570, p. 405-437.Garcia-Vallès, M., J. Prado, and M. Vendrell-Sax, 1994, Maceral distribution in Garumnian coals and palaeoenvironmental implications in the central Pyrenees, Spain: International Journal of Coal Geology, v. 25, p. 27-46.Gardner, T.W., E.G. Williams, and P.W. Holbrook, 1988, Pedogenesis of some Pennsylvanian underclays: Ground-water, topographic and tectonic controls: Geological Society of America Special Paper 216, p. 81-101.Garner, C., G. Finqueneisel, T. Zimny, Z. Pokryszka, S. Lafortune, P.D.C. Défossez, and E.C. Gaucher, 2011, Selection of coals of different maturities for CO2 storage by modeling of CH4 and CO2 adsorption isotherms: International Journal of Coal Geology, v. 87, p. 80-86.Garner, C., G. Finqueneisel, T. Zimny, Z. Pokryszka, S. Lafortune, P.D.C. Défossez, and E.C. Gaucher, 2011, Selection of coals of different maturities for CO2 storage by modeling of CH4 and CO2 adsorption isotherms: International Journal of Coal Geology, v. 87, p. 80-86.Gaschnitz, R., B.M. Krooss, and R. Littke, 1997, Coalbed methane: adsorptive gas storage capacity of coal seams in the Upper Carboniferous of the Ruhr basin, Germany (extended abstract): TSOP, Abstracts and Program, v. 14, p. 42-44.Gasem, K.A.M., J.E. Fitgerald, Z. Pan, M. Sudibandriyo, and R.L. Robinson, 2002, Modeling of gas adsorption on coalbeds (abstract): AAPG Annual Convention Official Program, v. 11, p. A60-61.Gash, B.W., 1991, Measurement of "rock properties" in coal for coalbed methane production: SPE paper 22909.Gastaldo, R.A., 2010, Peat or no peat: why do the Rajang and Mahakam deltas differ?: International Journal of Coal Geology, v. 83, p. 162-172.Gastaldo, R.A., and C.W. Degges, 2007, Sedimentology and paleontology of a Carboniferous log jam: International Journal of Coal Geology, v. 69, p. 103-118.Gastaldo, R.A., ed., 1989, Plant taphonomy—organic sedimentary processes: Review of Palaeobotany and Palynology, v. 58, p. 1-94.

Gastaldo, R.A., I.M. Stevanović-Walls, W.N. Ware, and S.F. Greb, 2004, Community heterogeneity of Early Pennsylvanian peat mires: Geology, v. 32, p. 693-696.Gastaldo, R.A., W.A. DiMichele, and H.W. Pfefferkorn, 1996, Out of the icehouse into the greenhouse: a late Paleozoic analog for modern global vegetational change: GSA Today, v. 6, no. 10, p. 1-7.Gatnar, K., and A. Tor, 2003, Drainage and economic utilization of methane from coal seams in the Jastrzebie mining field: Applied Energy, v. 74, p. 331-341.Gavin, M.J., 1922, Oil-shale. An historical, technical, and economic study: U.S. Bureau of Mines Bulletin 210, 201 p.Gayer, R. and I. Harris, eds., 1996, Coalbed methane and coal geology: London, Geological Society Special Publication 109, 344 p.Gayer, R., and D. Rickard, 1994, Colloform gold in coal from southern Wales: Geology, v. 22, p. 35-38.Gayer, R.A., and J. Pasek, 1997, European coal geology and technology: London, Geological Society Special Publication 125, 448 p.

Geboy, N.J., M.A. Engle, and J.C. Hower, 2013, Whole-coal versus ash basis in coal geochemistry: A mathematical approach to consistent interpretations: International Journal of Coal Geology, v. 113, p. 41-49.Geboy, N.J., R.A. Olea, M.A. Engle, J.A. Martín-Fernández, 2013, Using simulated maps to interpret the geochemistry, formation and quality of the Blue Gem coal bed, Kentucky, USA: International Journal of Coal Geology, v. 112, p. 26-35.

Galtier, J., 1997, Coal-ball floras of the Namurian-Westphalian of Europe, in P.C. Lyons and E.L. Zodrow, eds., Euramerican Carboniferous paleobotany and coal geology: Review of Palaeobotany and Palynology, v. 95, p. 51-72.

Gamson, P., B. Beamish, and D. Johnson, 1996, Coal microstructure and secondary mineralization: their effect on methane recovery, in R. Gayer and I. Harris, eds., Coalbed methane and coal geology: London, Geological Society Special Publication 109, p. 165-179.

García, C.P., M.I. Álvarez Fernández, C. González Nicieza, A.E. Álvarez Vigil, and F. López Gayarre, 2010, Storage of N 2, He and CH4 in coal: Study and application in a practical case in the central Asturian coal basin (northern Spain): International Journal of Coal Geology, v. 81, p. 53-63.García, C.P., M.I. Álvarez Fernández, C. González Nicieza, A.E. Álvarez Vigil, and F. López Gayarre, 2010, Storage of N 2, He and CH4 in coal: Study and application in a practical case in the central Asturian coal basin (northern Spain): International Journal of Coal Geology, v. 81, p. 53-63. Garcia-Gonzalez, M., D.B. MacGowan, and R.C. Surdam, 1993, Coal as a source rock of petroleum and gas - a comparison between natural and artificial maturation of the Almond Formation coals, Greater Green River basin in Wyoming, in D.G. Howell, ed., The future of energy gases: USGS Professional Paper 1570, p. 405-437.

Gastaldo, R.A., G.P. Allen, and A.Y. Huc, 1993, Detrital peat foundation in the tropical Mahakam River delta, Kalimantan, eastern Borneo: sedimentation, plant composition and geochemistry, in C.J. Cobb and C.B. Cecil, eds., Modern and ancient coal-forming environments: Geological Society of America Special Paper 286, p. 107-118.Gastaldo, R.A., I. Stevanovic-Walls, and W.N. Ware, 2004, Erect forests are evidence for coseismic base-level changes in Pennsylvanian cyclothems of the Black Warrior Basin, U.S.A., in J.C. Pashin and R.A. Gastaldo, eds., Sequence stratigraphy, paleoclimate, and tectonics of coal-bearing strata: AAPG Studies in Geology 51, p. 219-238.

Ge, E., and C. Wert, 1990, Spatial variation of organic sulfur in coal, in W.L. Orr and C.M. White, eds., Geochemistry of sulfur in fossil fuels: Washington, D.C., American Chemical Society Symposium Series 429, p. 316-325.

Geboy, N.J., R.A. Olea, M.A. Engle, J.A. Martín-Fernández, 2013, Using simulated maps to interpret the geochemistry, formation and quality of the Blue Gem coal bed, Kentucky, USA: International Journal of Coal Geology, v. 112, p. 26-35.Gelin, F., J.K. Volkman, C. Largeau, S. Derenne, J.S. Sinninghe Damste, and J.W. De Leeuw, 1999, Distribution of aliphatic, nonhydrolyzable biopolymers in marine microalgae: Organic Geochemistry, v. 30, p. 147-159.Gensterblum, Y., A. Merkel, A. Busch, and B.M. Krooss, 2013, High-pressure CH4 and CO2 sorption isotherms as a function of coal maturity and the influence of moisture: International Journal of Coal Geology, v. 118, p. 45-57.Gensterblum, Y., A. Merkel, A. Busch, BM. Krooss, and R. Littke, 2014, Gas saturation and CO2 enhancement potential of coalbed methane reservoirs as a function of depth: AAPG Bulletin, v. 98, p. 395-420. (CO2-ECBM)Gensterblum, Y., P. van Hemert, P. Billemont, E. Battistutta, A. Busch, B.M. Krooss, G. De Weireld, and K.-H.A.A. Wolf, 2010, European inter-laboratory comparison of high pressure CO2 sorption isotherms II: natural coals: International Journal of Coal Geology, v. 84, p. 115-124.Gentzis, T., 2000, Subsurface sequestration of carbon dioxide — an overview from an Alberta (Canada) perspective: International Journal of Coal Geology, v. 43, p. 287-305.Gentzis, T., 2000, Subsurface sequestration of carbon dioxide — an overview from an Alberta (Canada) perspective: International Journal of Coal Geology, v. 43, p. 287-305.Gentzis, T., 2006, Economic coalbed methane production in the Canadian Foothills: solving the puzzle: International Journal of Coal Geology, v. 65, p. 79-92.Gentzis, T., 2009, Stability analysis of a horizontal coalbed methane well in the Rocky Mountain Front Ranges of southeast British Columbia, Canada: International Journal of Coal Geology, v. 77, p. 328-337.Gentzis, T., 2013, Coalbed methane potential of the Paleocene Fort Union coals in south-central Wyoming, USA: International Journal of Coal Geology, v. 108, p. 27-34.Gentzis, T., A. Iacchelli, H. Whaley, D.P. Deshpande, and B. Ozüm, 1996, Combustion reactivity of Smoky River coal mine by-products: Energy Sources, v. 18, p. 151-166. "Combustion efficiency could be improved by increasing turbulence intensity in the furnace, by blending the coal with a more reactive fuel, or by reducing the ash content of the coal"Gentzis, T., and A. Chambers, 1993, A microscopic study of the combustion residues of subbituminous and bituminous coals from Alberta, Canada: International Journal of Coal Geology, v. 24, p. 245-257.Gentzis, T., and A. Chambers, 1995, Combustion properties of macerals from four Alberta coals: Energy Sources, v. 17, p. 655-680.Gentzis, T., and A. Chambers, 1995, Physical structure changes of Canadian coals during combustion: Energy Sources, v. 17, p. 131-149.Gentzis, T., and D. Bolen, 2008, The use of numerical simulation in predicting coalbed methane producibility from the Gates coal, Alberta Inner Foothills, Canada: Comparison with Mannville coal CBM production in the Alberta Syncline: International Journal of Coal Geology, v. 74, p. 215-236.Gentzis, T., and F. Goodarzi, 1989, Organic petrology of a self-burning coal wastepile from Coleman, Alberta, Canada: International Journal of Coal Geology, v. 11, p. 257-271.

Gentzis, T., and F. Goodarzi, 1991, Petrology, depositional environment and utilization potential of Devonian cannel coals from Melville Island, Canadian Arctic Islands: Bulletin de la Societe Geologique de France, v. 162, p. 239-253.Gentzis, T., and F. Goodarzi, 1991, Petrology, depositional environment and utilization potential of Devonian cannel coals from Melville Island, Canadian Arctic Islands: Bulletin de la Societe Geologique de France, v. 162, p. 239-253.Gentzis, T., and F. Goodarzi, 1991, Thermal maturity and hydrocarbon potential of the sedimentary succession from the Hecla field in Sverdrup basin, Arctic Canada: International Journal of Coal Geology, v. 19, p. 483-517.Gentzis, T., and F. Goodarzi, 1993, Regional thermal maturity in the Franklinian Mobile belt, Melville Island, Arctic Canada: Marine and Petroleum Geology, v. 10, p. 215-230.

Gentzis, T., D. Schoderbek, and S. Pollock, 2006, Evaluating the coalbed methane potential of the Gething coals in NE British Columbia, Canada: an example from the Highhat area, Peace River coalfield: International Journal of Coal Geology, v. 68, p. 135-150.Gentzis, T., F. Goodarzi, and L.R. Snowdon, 1993, Variation of maturity indicators (optical and Rock-Eval) with respect to organic matter type and matrix lithology: an example from Melville Island, Canadian Arctic Archipelago: Marine and Petroleum Geology, v. 10, p. 507-513.Gentzis, T., F. Goodarzi, and L.R. Snowdon, 1993, Variation of maturity indicators (optical and Rock-Eval) with respect to organic matter type and matrix lithology: an example from Melville Island, Canadian Arctic Archipelago: Marine and Petroleum Geology, v. 10, p. 507-513.Gentzis, T., F. Goodarzi, and L.R. Snowdon, 1993, Variation of maturity indicators (optical and Rock-Eval) with respect to organic matter type and matrix lithology: an example from Melville Island, Canadian Arctic Archipelago: Marine and Petroleum Geology, v. 10, p. 507-513.Gentzis, T., F. Goodarzi, and L.R. Snowdon, 1993, Variation of maturity indicators (optical and Rock-Eval) with respect to organic matter type and matrix lithology: an example from Melville Island, Canadian Arctic Archipelago: Marine and Petroleum Geology, v. 10, p. 507-513.Gentzis, T., F. Goodarzi, and R.A. McFarlane, 1992, Molecular structure of reactive coals during oxidation, carbonization and hydrogenation - an infrared photoacoustic spectroscopic and optical microscopic study: Organic Geochemistry, v. 18, p. 249-258.Gentzis, T., F. Goodarzi, and R.A. McFarlane, 1992, Molecular structure of reactive coals during oxidation, carbonization and hydrogenation—an infrared photoacoustic spectroscopic and optical microscopic study: Organic Geochemistry, v. 18, p. 249-258.Gentzis, T., F. Goodarzi, and R.A. McFarlane, 1992, Molecular structure of reactive coals during oxidation, carbonization and hydrogenation—an infrared photoacoustic spectroscopic and optical microscopic study: Organic Geochemistry, v. 18, p. 249-258.Gentzis, T., F. Goodarzi, F.K. Cheung, and F. Laggoun-Défarge, 2008, Coalbed methane producibility from the Mannville coals in Alberta, Canada: A comparison of two areas: International Journal of Coal Geology, v. 74, p. 237-249.Gentzis, T., F. Goodarzi, L.R. Snowdon, R.M. Bustin, and M. Labonte, 1991, The effect of mineral matrix and seam thickness on reflectance of vitrinite in high coals (abstract): AAPG Bulletin, v. 75, p. 1127.Gentzis, T., H. Hirosue, and T. Sakaki, 1996, Effect of rank and petrographic composition on the swelling behavior of coals: Energy Sources, v. 18, p. 131-141.Gentzis, T., H. Hirosue, and T. Sakaki, 1996, Effect of rank and petrographic composition on the swelling behavior of coals: Energy Sources, v. 18, p. 131-141.Gentzis, T., H. Hirosue, and T. Sakaki, 1996, Relationship between density and swelling ratio in a subbituminous and a high-volatile bituminous coal: Energy Sources, v. 18, p. 119-129.Gentzis, T., H. Hirosue, and T. Sakaki, 1996, Relationship between density and swelling ratio in a subbituminous and a high-volatile bituminous coal: Energy Sources, v. 18, p. 119-129.Gentzis, T., K. Murray, R. Klinger, and M. Santillan, 2006, Horizontal degasification and characterization of coals in the Sabinas sub-basin, Mexico: implications for CBM production: Bulletin of Canadian Petroleum Geology, v. 54, p. 221-237.Gentzis, T., N. Deisman, and R.J. Chalaturnyk, 2007, Geomechanical properties and permeability of coals from the Foothills and Mountain regions of western Canada: International Journal of Coal Geology, v. 69, p. 153-164.Gentzis, T., N. Deisman, and R.J. Chalaturnyk, 2009, A method to predict geomechanical properties and model well stability in horizontal boreholes: International Journal of Coal Geology, v. 78, p. 149-160.

Gentzis, T., and F. Goodarzi, 1990, A review of the use of bitumen reflectance in hydrocarbon exploration with examples from Melville Island, Arctic Canada, in V.F. Nuccio and C.E. Barker, eds., Applications of thermal maturity studies to energy exploration: SEPM, Rocky Mountain Section, p. 23-36.Gentzis, T., and F. Goodarzi, 1990, A review of the use of bitumen reflectance in hydrocarbon exploration with examples from Melville Island, Arctic Canada, in V.F. Nuccio and C.E. Barker, eds., Applications of thermal maturity studies to energy exploration: S.E.P.M., Rocky Mountain Section, p. 23-36.

Gentzis, T., and F. Goodarzi, 1994, Reflectance suppression in some Cretaceous coals from Alberta, Canada, in P.K. Mukhopadhyay and W.G. Dow, eds., Vitrinite reflectance as a maturity parameter: applications and limitations: American Chemical Society Symposium Series 570, p. 93-110.Gentzis, T., and F. Goodarzi, 1994, Reflectance suppression in some Cretaceous coals from Alberta, Canada, in P.K. Mukhopadhyay and W.G. Dow, eds., Vitrinite reflectance as a maturity parameter: applications and limitations: Washington, D.C., American Chemical Society Symposium Series 570, p. 93-110.

Gentzis, T., N. Deisman, and R.J. Chalaturnyk, 2009, Effect of drilling fluids on coal permeability: Impact on horizontal wellbore stability: International Journal of Coal Geology, v. 78, p. 177-191.Gentzis, T., T. de Freitas, F. Goodarzi, M. Melchin, and A. Lenz, 1996, Thermal maturity of lower Paleozoic sedimentary successions in Arctic Canada: AAPG Bulletin, v. 80, p. 1065-1084.George, J.D.St., and M.A. Barakat, 2001, The change in effective stress associated with shrinkage from gas desorption in coal: International Journal of Coal Geology, v. 45, p. 105-113.George, S.C., 1992, Effect of igneous intrusion on the organic geochemistry of a siltstone and an oil shale horizon in the Midland Valley of Scotland: Organic Geochemistry, v. 18, p. 705-723.George, S.C., and R.W.T. Wilkins, 2002, A review of the evidence for expulsion of commercial quantities of oil from humic coal (abstract): TSOP Annual Meeting, abstract A2.2.3.George, S.C., H. Volk, M. Ahmed, W. Pickel, and T. Allan, 2007, Biomarker evidence for two sources for solid bitumens in the Subu wells: Implications for the petroleum prospectivity of the east Papuan Basin: Organic Geochemistry, v. 38, p. 609-642.George, S.C., J.W. Smith, and D.R. Jardine, 1994, Vitrinite reflectance suppression in coal due to marine transgression: Case study of the organic geochemistry of the Greta Seam, Sydney Basin: Australian Petroleum Exploration Association Journal, v. 34, p. 241-255.George, S.C., S.M. Llorca, and P.J. Hamilton, 1994, An integrated analytical approach for determining the origin of solid bitumens in the McArthur basin, northern Australia: Organic Geochemistry, v. 21, p. 235-248.George, S.C., T.E. Ruble, A. Dutkiewicz, and P.J. Eadington, 2001, Assessing the maturity of oil trapped in fluid inclusions using molecular geochemistry data and visually-determined fluorescence colours: Applied Geochemistry, v. 16, p. 451-473.Gerdon, C.J., T.F. Anderson, and T.L. Phillips, 1997, Petrography and geochemistry of North American and European coal balls: Implications for coal-ball origins (abstract): Geological Society of America, Abstracts with Programs, v. 29, no. 4, p. 16.Gerlach, J.B., and K.R. Cercone, 1993, Former Carboniferous overburden in the northern Appalachian basin: a reconstruction based on vitrinite reflectance: Organic Geochemistry, v. 20, p. 223-232.

Ghosh, S., P. Jha, and A.S. Vidyarthi, 2014, Unraveling the microbial interactions in coal organic fermentation for generation of methane — A classical to metagenomic approach: International Journal of Coal Geology, v. 125, p. 36-44.Ghosh, T.K., 1971, Change in coal macerals: Fuel, v. 50, p. 218-221.Giavarini, C., F. Maccioni, and M.L. Santarelli, 2009, CO2 sequestration from coal fired power plants: Fuel, v. 89, p. 623-628.Gibb, W.H., F. Clarke, and A.K. Mehta, 2000, The fate of coal mercury during combustion: Fuel Processing Technology, v. 65, p. 365-377.Gibling, M.R., and D.J. Bird, 1994, Late Carboniferous cyclothems and alluvial paleovalleys in the Sydney Basin, Nova Scotia: Geological Society of America Bulletin, v. 106, p. 105-117.Gibling, M.R., D.L. Marchioni, and W.D. Kalkreuth, 1994, Detrital and organic facies of upper Carboniferous strata at Mabou mines, western Cape Breton Island, Nova Scotia: Geological Survey of Canada, Current Research 1994-D, p. 51-56.

Gibling, M.R., M. Zentilli, and R.G.L. McCready, 1989, Sulphur in Pennsylvanian coals of Atlantic Canada: geologic and isotopic evidence for a bedrock evaporate source: International Journal of Coal Geology, v. 11, p. 81-104.

Giles, A.W., 1930, Peat as a climatic indicator: Geological Society of America Bulletin, v. 41, p. 405-430.Giles, A.W., 1930, Pennsylvanian climates and paleontology: AAPG Bulletin, v. 14, p. 1279-1299.Gill, S., and K. Yemane, 1996, Implications of a Lower Pennsylvanian ultisol for equatorial Pangean climates and early, oliogotrophic, forest ecosystems: Geology, v. 24, p. 905-908.Gill, W., N.A. Brown, C.D.A. Coin, and M.R. Mahoney, 1985, The influence of ash on the weakening of coke: Iron and Steel Society Conference Proceedings, v. 44, p. 233-238.Gilleland, K., 2008, Growing coalbed assets: An Investor’s Guide to Unconventional Gas: Shales and Coalbed Methane, Supplement to Oil & Gas Investor, January 2008, p. 32-37.Gilliland, E.S., N. Ripepi, M. Conrad, M.J. Miller, and M. Karmis, 2013, Selection of monitoring techniques for a carbon storage and enhanced coalbed methane recovery pilot test in the central Appalachian Basin: International Journal of Coal Geology, v. 118, p. 105-112.Gin, T.T., C.L. Dahl, and D.G. Wilson, 1963, Petrographic evaluation of coking coals: American Iron and Steel Institute National Meeting, p. 205-225.

Ginsberg, S., 2012, EPA considers rule for shale gas and CBM water discharges: American Oil & Gas Reporter, v. 55, no. 1, p. 27.

Given, P.H., A. Davis, D. Kuehn, P.C. Painter, and W. Spackman, 1985, A multi-facetted study of a Cretaceous coal with algal affinities. I. Provenance of the coal samples and basic compositional data: International Journal of Coal Geology, v. 5, p. 247-260.

Given, P.H., and W. Spackman, 1978, Reporting of analyses of low-rank coals on the dry, mineral-matter-free basis: Fuel, v. 57, p. 319.Given, P.H., and W. Spackman, 1979, Reporting inorganic matter in low-rank coal analysis: Fuel, v. 58, p. 901.

Gerstein, B.C., P.D. Murphy, and L.M. Ryan, 1982, Aromaticity in coal, in R.A. Meyers, ed., Coal strucuture: New York, Academic Press, p. 87-129.

Gibling, M.R., K.I. Saunders, N.E. Tibert, and J.A. White, 2004, Sequence sets, high-accommodation events, and the coal window in the Carboniferous Sydney coalfield, Atlantic Canada, in J.C. Pashin and R.A. Gastaldo, eds., Sequence stratigraphy, paleoclimate, and tectonics of coal-bearing strata: AAPG Studies in Geology 51, p. 169-197.

Gielisch, H., 2007, Detecting concealed coal fires, in G.B. Stracher, ed., Geology of coal fires: case studies from around the world: GSA Reviews in Engineering Geology 18, p. 199-210.

Ginnard, K.J., and M.P. Corriveau, 1978, Correlation of weathered lignite with pH and depth of cover, in R.R. Dutcher, ed., Field description of coal: Philadelphia, PA, American Society for Testing and Materials, Special Technical Publication 661, p. 41-49.

Given, P.H., 1972, Biological aspects of the geochemistry of coal, in Advances in organic geochemistry 1971: Oxford, Pergamon Press, p. 69-92.Given, P.H., 1976, Some comments on the chemistry of the agglomerating tendency of coals, in C.J. Smith, compiler, Proceedings of the coal agglomeration and conversion symposium: West Virginia Geological and Economic Survey, p. 3-8.Given, P.H., 1984, An essay on the organic geochemistry of coal, in M.L. Gorbaty, J.W. Larsen, and I. Wender, eds., Coal science, v. 3: New York, Academic Press, p. 63-252.Given, P.H., 1988, The origin of coals, in Y. Yurum, ed., New trends in coal science: Boston, Kluwer Academic Publishers, p. 1-52.Given, P.H., 1988, The origin of coals, in Y. Yürüm, ed., New trends in coal science: Boston, Kluwer Academic Publishers, p. 1-52.

Given, P.H., and A.D. Cohen, eds., 1977, Interdisciplinary studies of peat and coal origins: Geological Society of America Microform Publication 7, 173 p. (http://www.caer.uky.edu/publications/gsapub7/gsapub7.shtml)Given, P.H., and G.R. Dyrkacz, 1988, The nature and origins of coal macerals, in Y. Yurum, ed., New trends in coal science: Boston, Kluwer Academic Publishers, p. 53-72.Given, P.H., and G.R. Dyrkacz, 1988, The nature and origins of coal macerals, in Y. Yürüm, ed., New trends in coal science: Boston, Kluwer Academic Publishers, p. 53-72.

Given, P.H., D.C. Cronauer, W. Spackman, H.L. Lovell, A. Davis, and B. Biswas, 1975, Dependence of coal liquefaction behaviour on coal characteristics. 1. Vitrinite-rich samples: Fuel, v. 54, p. 34-39.Given, P.H., D.C. Cronauer, W. Spackman, H.L. Lovell, A. Davis, and B. Biswas, 1975, Dependence of coal liquefaction behaviour on coal characteristics. 2. Role of petrographic composition: Fuel, v. 54, p. 40-49.Given, P.H., M.E. Peover, and W.F. Wyss, 1960, Chemical properties of coal macerals. I. Introductory survey and some properties of exinites: Fuel, v. 39, p. 323-340.

Given, P.H., W. Spackman, A. Davis, J. Zoeller, R.G. Jenkins, and R. Khan, 1984, Chemistry of some maceral concentrates from British coals. Provenance of samples and basic compositional data: Fuel, v. 63, p. 1655-1659.Given, P.H., W. Spackman, A. Davis, J. Zoeller, R.G. Jenkins, and R. Khan, 1984, Chemistry of some maceral concentrates from British coals. Provenance of samples and basic compositional data: Fuel, v. 63, p. 1655-1659.Given, P.H., W. Spackman, J.R. Imbalzano, D.J. Casagrande, A.J. Lucas, W. Cooper, and C. Exarchos, 1983, Physiochemical characteristics and levels of microbial activity in some Florida peat swamps: International Journal of Coal Geology, v. 3, p. 77-99.Given, P.H., W. Spackman, P.C. Painter, C.A. Rhoads, N.J. Ryan, L. Alemany, and R.J. Pugmire, 1984, The fate of cellulose and lignin in peats: an exploratory study of the input to coalification: Organic Geochemistry, v. 6, p. 399-407.

Glass, G.B., and R.M. Lyman, 1998, Geology of Wyoming’s Powder River Basin coalfield: Mining Engineering, v. 50, no. 7, p. 33-39.Glasspool, I.J., 2003, Hypautochthonous-allochthonous coal deposition in the Permian, South African, Witbank Basin No. 2 seam; a combined approach using sedimentology, coal petrology and palaeontology: International Journal of Coal Geology, v. 53, p. 81-135.Glasspool, I.J., D. Edwards, and L. Axe, 2004, Charcoal in the Silurian as evidence for the earliest wildfire: Geology, v. 32, p. 381-383.Glasspool, I.J., D. Edwards, and L. Axe, 2004, Charcoal in the Silurian as evidence for the earliest wildfire: Geology, v. 32, p. 381-383.Glasspool, I.J., D. Edwards, and L. Axe, 2006, Charcoal in the Early Devonian: A wildfire-derived Konservat-Lagerstätte: Review of Palaeobotany and Palynology, v. 142, p. 131-136.Glasspool, I.J., D. Edwards, and L. Axe, 2006, Charcoal in the Early Devonian: A wildfire-derived Konservat-Lagerstätte: Review of Palaeobotany and Palynology, v. 142, p. 131-136.

Gleit, A., W. Moran, and A. Jung, 1986, Coal sampling and analysis: methods and models: Park Ridge, N.J., Noyes Publications, 188 p.Glick, D.C., and A. Davis, 1987, Variability in the inorganic element content of U.S. coals including results of cluster analysis: Organic Geochemistry, v. 11, p. 331-342.Glick, D.C., and A. Davis, 1987, Variability in the inorganic element content of U.S. coals including results of cluster analysis: Organic Geochemistry, v. 11, p. 331-342.Glick, D.C., and A. Davis, 1991, Operation and composition of the Penn State Coal Sample Bank and Data Base: Organic Geochemistry, v. 17, p. 421-430.Glick, D.C., G.D. Mitchell, and A. Davis, 2005, Coal sample preservation in foil multilaminate bags: International Journal of Coal Geology, v. 63, p. 178-189.Glikson, M., and C. Fielding, 1991, The Late Triassic Callide coal measures, Queensland, Australia: coal petrology and depositional environment: International Journal of Coal Geology, v. 17, p. 313-332. (origin of micrinite)

Glikson, M., D. Taylor, and D. Morris, 1992, Lower Palaeozoic and Precambrian petroleum source rocks and the coalification path of alginite: Organic Geochemistry, v. 18, p. 881-897.Glikson, M., D. Taylor, and D. Morris, 1992, Lower Palaeozoic and Precambrian petroleum source rocks and the coalification path of alginite: Organic Geochemistry, v. 18, p. 881-897.Glikson, M., D. Taylor, and D. Morris, 1992, Lower Paleozoic and Precambrian petroleum source rocks and the coalification path of alginite: Organic Geochemistry, v. 18, p. 881-897. (bitumens suppress Tmax)

Gluskoter, H.J., and J.A. Simon, 1968, Sulfur in Illinois coals: Illinois State Geological Survey Circular 432, 28 p.Gluskoter, H.J., and M.E. Hopkins, 1970, Distribution of sulfur in Illinois coals: Illinois State Geological Survey, Guidebook 8, p. 89-95.Gluskoter, H.J., and O.W. Rees, 1964, Chlorine in Illinois coal: Illinois State Geological Survey Circular 372, 23 p.Gluskoter, H.J., R.R. Ruch, W.G. Miller, R.A. Cahill, G.B. Dreher, and J.K. Kuhn, 1977, Trace elements in coal: occurrence and distribution: Illinois State Geological Survey Circular 499, 154 p.Gluskoter, H.J., R.R. Ruch, W.G. Miller, R.A. Cahill, G.B. Dreher, and J.K. Kuhn, 1977, Trace elements in coal: occurrence and distribution: Illinois State Geological Survey Circular 499, 154 p.Gluskoter, H.J., R.R. Ruch, W.G. Miller, R.A. Cahill, G.B. Dreher, and J.K. Kuhn, 1977, Trace elements in coal: occurrence and distribution: Illinois State Geological Survey Circular 499, 154 p.Godec, M., G. Koperna, R. Petrusak, and A. Oudinot, 2013, Potential for enhanced gas recovery and CO2 storage in the Marcellus Shale in the eastern United States: International Journal of Coal Geology, v. 118, p. 95-104.

Given, P.H., R.N. Miller, N. Suhr, and W. Spackman, 1975, Major, minor, and trace elements in the liquid product and solid residue from catalytic hydrogenation of coals, in S. Babu, ed., Trace elements in fuel: American Chemical Society, Advances in Chemistry Series 141, p. 188-191.Given, P.H., S. Spackman, A. Davis, and R.G. Jenkins, 1982, Some proved and unproved effects of coal geochemistry on liquefaction behavior with emphasis on U.S. coals, in D.D. Whitehurst, and others, eds., Liquefaction fundamentals: American Chemical Society, Symposium Series 139, p. 3-34.Given, P.H., W. Spackman, A. Davis, and R.G. Jenkins, 1980, Some proved and unproved effects of coal geochemistry on liquefaction behavior with emphasis on U.S. coals, in D.D. Whitehurst, ed., Coal liquefaction fundamentals: Washington, D.C., American Chemical Society, Symposium Series 139, p. 3-34.

Gize, A.P., 1990, Petroleum-derived cokes in sedimentary basins, in W.J.J. Fermont and J.W. Weegink, eds., International symposium on organic petrology: Mededelingen Rijks Geologische Dienst, v. 45, p. 65-73.Gize, A.P., 1993, The analysis of organic matter in ore deposits, in J. Parnell, H. Hucka, and P. Landais, eds., Bitumens in ore deposits: New York, Springer-Verlag, p. 28-52.

Gleason, P.J., A.D. Cohen, W.G. Smith, J.K. Brooks, P.A. Stone, R.I. Goodrick, and W. Spackman, 1974, The environmental significance of Holocene sediments from the Everglades and saline tidal plain, in P.J. Gleason, ed., Environments of south Florida: present and past: Miami Geological Society Memoir 2, p. 297-341.Gleason, P.J., and W. Spackman, 1974, Calcareous periphyton and water chemistry in the Everglades, in P.J. Gleason, ed., Environments of south Florida: present and past: Miami Geological Society Memoir 2, p. 146-181.

Glikson, M., and G.H. Taylor, 1986, Cyanobacterial mats: major contributors to the organic matter in Toolebuc Formation oil shales, in D.I. Gravestock, P.S. Moore, and G.M. Pitt, eds., Contributions to the geology and hydrocarbon potential of the Eromanga basin: Geological Society of Australia Special Publication 12, p. 273-286.Glikson, M., C.J. Boreham, and D.S. Thiede, 1999, Coal composition and mode of maturation, a determining factor in quantifying hydrocarbon species generated, in M. Mastalerz, M. Glikson, and S.D. Golding, eds., Coalbed methane: scientific, environmental and economic evaluation: Boston, Kluwer Academic Publishers, p. 155-185. (bitumen)Glikson, M., C.J. Boreham, and D.S. Thiede, 1999, Coal composition and mode of maturation, a determining factor in quantifying hydrocarbon species generated, in M. Mastalerz, M. Glikson, and S.D. Golding, eds., Coalbed methane: scientific, environmental and economic evaluation: Boston, Kluwer Academic Publishers, p. 155-185. (bitumen)

Glikson, M., K. Lindsay, and J. Saxby, 1989, Botryococcus - a planktonic green alga, the source of petroleum throught the ages: transmission electron microscopical studies of oil shales and petroleum source rocks: Organic Geochemistry, v. 14, p. 595-608.Gluskoter, H.J., 1991, Coal; a brief overview, inH.J. Gluskoter, D.D. Rice, and R.B. Taylor, eds., Economic geology, U.S.: Geological Society of America, The Geology of North America, v. P-2, p. 463-467.

Godec, M., G. Koperna, R. Petrusak, and A. Oudinot, 2013, Potential for enhanced gas recovery and CO2 storage in the Marcellus Shale in the eastern United States: International Journal of Coal Geology, v. 118, p. 95-104.Godec, M., T. Van Leeuwen, and V.A. Kuuskraa, 2007, Unconventional gas—5. Rising drilling, stimulation costs pressure economics: Oil & Gas Journal, v. 105.39, p. 45-51.Golab, A., C.R. Ward, A. Permana, P. Lennox, and P. Botha, 2013, High-resolution three-dimensional imaging of coal using microfocus X-ray computed tomography, with special reference to modes of mineral occurrence: International Journal of Coal Geology, v. 113, p. 97-108.Golab, A.N., A.C. Hutton, and D. French, 2007, Petrography, carbonate mineralogy and geochemistry of thermally altered coal in Permian coal measures, Hunter Valley, Australia: International Journal of Coal Geology, v. 70, p. 150-165.Golab, A.N., P.F. Carr, and D.R. Palamara, 2006, Influence of localised igneous activity on cleat dawsonite formation in Late Permian coal measures, Upper Hunter Valley, Australia: International Journal of Coal Geology, v. 66, p. 296-304.Gold, D., B. Hazen, and W.G. Miller, 1999, Colloidal and polymeric nature of fossil amber: Organic Geochemistry, v. 30, p. 971-983.Golden, J.F., and W. Hunn, 1980, Microstructural analysis by new image analysis techniques: Microsc. Sci., v. 8, p. 305-309.Golding, S.D., C.J. Boreham, and J.S. Esterle, 2013, Stable isotope geochemistry of coal bed and shale gas and related production waters: A review: International Journal of Coal Geology, v. 120, p. 24-40.

Golightly, D.W., and F.O. Simon, eds., 1989, Methods for sampling and inorganic analysis of coal: U.S. Geological Survey Bulletin 1823, 72 p.Golightly, D.W., and F.O. Simon, eds., 1989, Methods for sampling and inorganic analysis of coal: U.S. Geological Survey Bulletin 1823, 72 p.Golitsyn, M.V., I.V. Yeremin, and V.F. Cherepovskiy, 1983, Coals for synthetic-fuel production: International Geology Review, v. 25, no. 11, p. 1319-1327.Golombok, M., and D. Nikolic, 2008, Assessing contaminated gas: Hart’s E&P, v. 81, no. 6, p. 73-75.

Goodarzi, F., 1983, A comparison of optical properties of carbonized sporinite and vitrinite concentrates of coals of the same rank: Journal of Microscopy, v. 132, pt. 3, p. 279-288.Goodarzi, F., 1984, Chitinous fragments in coal: Fuel, v. 63, p. 1504-1507.Goodarzi, F., 1984, Optical properties of high temperature heat-treated vitrinites: Fuel, v. 63, p. 820-826.Goodarzi, F., 1984, Organic petrography of graptolite fragments from Turkey: Marine and Petroleum Geology, v. 1, p. 202-210.Goodarzi, F., 1985, Dispersion of optical properties of graptolite epiderms with increased maturity in early Paleozoic organic-rich sediments: Fuel, v. 64, p. 1735-1740.Goodarzi, f., 1985, Optical properties of vitrinite carbonized at different pressures: Fuel, v. 64, p. 156-162.Goodarzi, F., 1985, Optical properties of vitrinite carbonized under pressure: Fuel, v. 64, p. 158-162.Goodarzi, F., 1985, Optically anisotropic fragments in a western Canadian subbituminous coal: Fuel, v. 64, p. 1294-1300.Goodarzi, F., 1985, Optically anisotropic fragments in a western Canadian subbituminous coal: Fuel, v. 64, p. 1294-1300.Goodarzi, F., 1985, Preservation and characteristics of plant remains in Iranian natural bitumens: International Journal of Coal Geology, v. 4, p. 321-334.Goodarzi, F., 1985, Reflected light microscopy of chitinozoan fragments: Marine and Petroleum Geology, v. 2, p. 72-78.Goodarzi, F., 1985, Reflected light microscopy of chitinozoan fragments: Marine and Petroleum Geology, v. 2, p. 72-78.Goodarzi, F., 1986, Optical properties of oxidized resinites: Fuel, v. 65, p. 260-265.Goodarzi, F., 1987, Comparison of reflectance data from various macerals from sub-bituminous coals: Journal of Petroleum Geology, v. 10, p. 219-226.Goodarzi, F., 1987, Exsudatinite in Carboniferous oil shales from Arctic Canada: Fuel, v. 66, p. 771-773.Goodarzi, F., 1987, The use of automated image analysis in coal petrology: Canadian Journal of Earth Sciences, v. 24, p. 1064-1069.

Goodarzi, F., 2002, Mineralogical and elemental composition of Canadian feed coal: Fuel, v. 81, p. 1199-1213.Goodarzi, F., 2004, Speciation and mass-balance of mercury from coal fired power plants burning western Canadian subbituminous coal, Alberta, Canada: Journal of Environmental Monitoring, v. 6, p. 792-798.Goodarzi, F., 2005, Petrology of subbituminous feed coal as a guide to the capture of mercury by fly ash—influence of depositional environment: International Journal of Coal Geology, v. 61, p. 1-12.Goodarzi, F., 2006, Assessment of elemental content of milled coal, combustion residues, and stack emitted materials: possible environmental effects for a Canadian pulverized coal-fired power plant: International Journal of Coal Geology, v. 65, p. 17-25.Goodarzi, F., 2006, Assessment of elemental content of milled coal, combustion residues, and stack emitted materials: possible environmental effects for a Canadian pulverized coal-fired power plant: International Journal of Coal Geology, v. 65, p. 17-25.Goodarzi, F., and A.C. Higgins, 1987, Optical properties of scolecodonts and their use as indicators of thermal maturity: Marine Petroleum Geology, v. 4, p. 353-359.Goodarzi, F., and A.R. Cameron, 1990, Organic petrology and elemental distribution in thermally altered coals from Telkwa, British Columbia: Energy Sources, v. 12, p. 315-343. (natural coking)Goodarzi, F., and B.S. Norford, 1985, Graptolites as indicators of the temperature histories of rocks: Journal of the Geological Society, London, v. 142, part 6, p. 1089-1099.Goodarzi, F., and B.S. Norford, 1987, Optical properties of graptolite epiderm -- a review: Bulletin Geol. Soc. Denmark, v. 35, p. 141-147.Goodarzi, F., and B.S. Norford, 1989, Variation of graptolite reflectance with depth of burial: International Journal of Coal Geology, v. 11, p. 127-141.

Golding, S.D., K.A. Baublys, M. Glikson, I.T. Uysal, and C.J. Boreham, 1999, Source and timing of coal seam gas generation in Bowen basin coals, in M. Mastalerz, M. Glikson, and S.D. Golding, eds., Coalbed methane: scientific, environmental and economic evaluation: Boston, Kluwer Academic Publishers, p. 257-269.(carbon isotope composition)

Gonzalez, E., H. Ferket, J.-P. Callot, N. Guilhaumou, S> Ortuno, and F. Roure, 2012, Paleoburial, hydrocarbon generation, and migration in the Córdoba platform and Veracruz Basin: Insights from fluid inclusion studies and two-dimensional (2D) basin modeling, in N.B. Harris and K.E. Peters, eds., Analyzing the thermal history of sedimentary basins: Methods and case studies: SEPM Special Publication 103, p. 167-186.

Goodarzi, F., 1990, Graptolite reflectance and thermal maturity of lower Paleozoic rocks, in V.F. Nuccio and C.E. Barker, eds., Applications of thermal maturity studies to energy exploration: SEPM, Rocky Mountain Section, p. 19-22.

Goodarzi, F., and D. G Murchison, 1976, Petrography and anisotropy of carbonized preoxidized coals: Fuel, v. 55, p. 141-147.Goodarzi, F., and D.G. Murchison, 1972, Optical properties of carbonized vitrinites: Fuel, v. 51, p. 322-328.Goodarzi, F., and D.G. Murchison, 1973, Optical properties of carbonized preoxidized vitrinites: Fuel, v. 52, p. 164-167.Goodarzi, F., and D.G. Murchison, 1973, Oxidized vitrinites -- their aromaticity, optical properties and possible detection: Fuel, v. 52, p. 90-92.Goodarzi, F., and D.G. Murchison, 1973, Oxidized vitrinites—their aromaticity, optical properties and detection: Fuel, v. 52, p. 90-92.

Goodarzi, F., and D.G. Murchison, 1976, Petrography and anisotropy of carbonized pre-oxidized coals: Fuel, v. 55, p. 141-147.Goodarzi, F., and D.G. Murchison, 1977, Effect of prolonged heat on the optical properties of vitrinite: Fuel, v. 56, p. 89-96.Goodarzi, F., and D.G. Murchison, 1977, Effect of prolonged heating on the optical properties of vitrinite: Fuel, v. 56, p. 89-96.Goodarzi, F., and D.G. Murchison, 1978, Influence of heating rate variation on the anisotropy of carbonized vitrinite: Fuel, v. 57, p. 273-284.Goodarzi, F., and D.G. Murchison, 1978, Influence of heating rate variation on the anisotropy of carbonized vitrinites: Fuel, v. 57, p. 273-284.Goodarzi, F., and D.G. Murchison, 1988, Retention of botanical structure in anthracitic vitrinites carbonized at high temperatures: Fuel, v. 67, p. 831-833.Goodarzi, F., and D.J. Swaine, 1993, Behavior of boron in coal during natural and industrial combustion processes: Energy Sources, v. 15, p. 609-622.Goodarzi, F., and D.J. Swaine, 1993, Behavior of Boron in coal during natural and industrial combustion processes: Energy Sources, v. 15, p. 609-622.Goodarzi, F., and D.J. Swaine, 1993, Chalcophile elements in western Canadian coals: International Journal of Coal Geology, v. 24, p. 281-292.Goodarzi, F., and D.J. Swaine, 1994, Paleoenvironmental and environmental implications of the boron content of coals: Geological Survey of Canada Bulletin 471, 76 p.Goodarzi, F., and D.J. Swaine, 1994, The influence of geological factors on the concentration of boron in Australian and Canadian coals: Chemical Geology, v. 118, p. 301-318.Goodarzi, F., and E. Van Der Flier-Keller, 1990, Variation of elements in the southern intermontane coals of British Columbia, Canada: Journal of Coal Quality, v. 9, p. 62-65.

Goodarzi, F., and F.E. Higgins, 2004, Speciation of nickel in Canadian subbituminous and bituminous feed coals and their ash byproductions: Journal of Environmental Monitoring, v. 6, p. 787-791.Goodarzi, F., and F.E. Higgins, 2005, Speciation of arsenic in Canadian subbituminous and bituminous feed coals and their ash byproducts: Energy and Fuel, v. 9, p. 905-915.Goodarzi, F., and F.E. Higgins, 2005, Speciation of chromium in Canadian subbituminous and bituminous feed coals and their ash byproducts: Energy and Fuel, v. 9, p. 2500-2508.Goodarzi, F., and J. Hower, 2007, Classification of carbon in Canadian fly ashes: Fuel, v. 48, p. 1949-1957.Goodarzi, F., and J.M. Vleeskens, 1988, Reactivity of bituminous-semianthracitic coals: a reflected light study of their combustion residues (fly ash): Journal of Coal Quality, v. 7, p. 80-85.

Goodarzi, F., and L.D. Stasiuk, 1991, Thermal alteration of gilsonite due to bushfire, an example from southwest Iran: International Journal of Coal Geology, v. 17, p. 333-342.Goodarzi, F., and N.N. Goodarzi, 2004, Mercury in western Canadian subbituminous coal—a weighted average study to evaluate potential mercury reduction by selective mining: International Journal of Coal Geology, v. 58, p. 251-259.Goodarzi, F., and P.F.V. Williams, 1986, Composition of natural bitumens and asphalts from Iran, part 2, bitumens from the Posteh Ghear Valley, southwest Iran: Fuel, v. 65, p. 17-28.Goodarzi, F., and R.A. McFarlane, 1991, Chemistry of fresh and weathered resinites—an infrared photoacoustic spectroscopic study: International Journal of Coal Geology, v. 19, p. 283-301.Goodarzi, F., and R.W. Macqueen, 1990, Optical/compositional character of six bitumen species from Middle Devonian rocks of the Pine Point Pb-Zn property, Northwest Territories, Canada: International Journal of Coal Geology, v. 14, p. 197-216.

Goodarzi, F., and T. Gentzis, 1991, Petrology, depositional environment and utilization potential of Devonian cannel coals from Melville Island, Arctic Canada: Bull. Soc. Geol. Fr., v. 162, p. 239-253.Goodarzi, F., and T. Gentzis, 1991, Petrology, depositional environment and utilization potential of Devonian cannel coals from Melville Island, Arctic Canada: Bulletin Soc. Geol. Fr., v. 162, p. 239-253.Goodarzi, F., D.A. Grieve, H. Sanei, T. Gentzis, and N.N. Goodarzi, 2009, Geochemistry of coals from the Elk Valley coalfield, British Columbia, Canada: International Journal of Coal Geology, v. 77, p. 246-259.Goodarzi, F., F.E. Huggins, and H. Sanei, 2008, Assessment of elements, speciation of As, Cr, Ni and emitted Hg for a Canadian power plant burning bituminous coal: International Journal of Coal Geology, v. 74, p. 1-12.Goodarzi, F., F.E. Huggins, and H. Sanei, 2008, Assessment of elements, speciation of As, Cr, Ni and emitted Hg for a Canadian power plant burning bituminous coal: International Journal of Coal Geology, v. 74, p. 1-12.Goodarzi, F., G. Herman, M. Iley, and H. Marsh, 1975, Carbonization and liquid crystal (mesophase) development. 6. Effect of pre-oxidation of vitrinite upon coking properties: Fuel, v. 54, p. 105-112.

Goodarzi, F., and D.G. Murchison, 1976, Optical properties of carbonized preoxidized vitrinites, in M.A. Nettleton and others, Coal I: current advances in coal chemistry and mining techniques: New York, MSS Information Corporation, p. 86-94.Goodarzi, F., and D.G. Murchison, 1976, Optical properties of carbonized vitrinites, in M.A. Nettleton and others, Coal I: current advances in coal chemistry and mining techniques: New York, MSS Information Corporation, p. 130-146.Goodarzi, F., and D.G. Murchison, 1976, Oxidized vitrinites - their aromaticity, optical properties and possible detection, in M.A. Nettleton and others, Coal I: current advances in coal chemistry and mining techniques: New York, MSS Information Corporation, p. 123-129.

Goodarzi, F., and E. van der Flier-Keller, 1991, Geological controls and constraints on the concentration of elements in western Canadian coals, in D.C. Peters, ed., Geology in coal resource utilization: Fairfax, VA, Techbooks, p. 389-412 (available from AAPG)

Goodarzi, F., and L.D. Stasiuk, 1987, Amorphous kerogen: bituminite in the Second White Speckled Shale, southern Saskatchewan, in Current research part A: Geological Society of Canada Paper 87-1A, p. 349-352.Goodarzi, F., and L.D. Stasiuk, 1987, Graptolite preparation for reflected light microscopy -- a technical note, in Current research part A: Geological Survey of Canada Paper 87-1A, p. 317-322.

Goodarzi, F., and R.W. Macqueen, 1993, Geochemistry and petrology of bitumen with respect to hydrocarbon generation and mineralization, in F. Goodarzi and R.W. Macqueen, eds., Geochemistry and petrology of bitumen with respect to hydrocarbon generation and mineralization: Energy Sources, v. 15, p. 177-180.Goodarzi, F., and T. Gentzis, 1991, Geological controls on the self-burning of coal seams, in D.C. Peters, ed., Geology in coal resource utilization: Fairfax, VA, TechBooks, p. 559-575.

Goodarzi, F., H. Sanei, L.D. Stasiuk, H. Bagheri-Sadeghi, and J. Reyes, 2006, A preliminary study of mineralogy and geochemistry of four coal samples from northern Iran: International Journal of Coal Geology, v. 65, p. 35-50.Goodarzi, F., H. Sanei, L.D. Stasiuk, H. Bagheri-Sadeghi, and J. Reyes, 2006, A preliminary study of mineralogy and geochemistry of four coal samples from northern Iran: International Journal of Coal Geology, v. 65, p. 35-50.Goodarzi, F., J. Reyes, J. Schulz, D. Hollman, and D. Rose, 2006, Parameters influencing the variation in mercury emissions from an Alberta power plant burning high inertinite coal over thirty-eight weeks period: International Journal of Coal Geology, v. 65, p. 26-34.Goodarzi, F., L. Snowdon, T. Gentzis, and D. Pearson, 1994, Petrological and chemical characteristics of liptinite-rich coals from Alberta, Canada: Marine and Petroleum Geology, v. 11, p. 307-319.Goodarzi, F., L. Snowdon, T. Gentzis, and D. Pearson, 1994, Petrological and chemical characteristics of liptinite-rich coals from Alberta, Canada: Marine and Petroleum Geology, v. 11, p. 307-319.Goodarzi, F., L. Snowdon, T. Gentzis, and D. Pearson, 1994, Petrological and chemical characteristics of liptinite-rich coals from Alberta, Canada: Marine and Petroleum Geology, v. 11, p. 307-319.Goodarzi, F., L. Snowdon, T. Gentzis, and D. Pearson, 1994, Petrological and chemical characteristics of liptinite-rich coals from Alberta, Canada: Marine and Petroleum Geology, v. 11, p. 307-319.Goodarzi, F., L.D. Stasiuk, and K. Lindholm, 1988, Graptolite reflectance and thermal maturity of Lower and Middle Ordovician shales from Scania, Sweden: Geologiska Foreningens I Stockholm Forhandlingar, v. 110, part 3, p. 225-236.Goodarzi, F., L.R. Snowdon, P.R. Gunther, and W.A.M. Jenkins, 1985, Preliminary organic petrography of Palaeozoic rocks from the Grand Banks, Newfoundland: Marine and Petroleum Geology, v. 2, p. 254-259.

Goodarzi, F., O.R. Eckstrand, L. Snowdon, B. Williamson, and L.D. Stasiuk, 1992, Thermal metamorphism of bitumen in Archaen rocks by ultramafic volcanic flows: International Journal of Coal Geology, v. 20, p. 165-178.Goodarzi, F., P.W. Brooks, and A.F. Embry, 1989, Regional maturity as determined by organic petrography and geochemistry of the Schei Point Group (Triassic) in the western Sverdrup Basin, Canadian Arctic Archipelago: Marine and Petroleum Geology, v. 6, p. 290-302.

Goodarzi, F., T. Gentzis, and R.M. Bustin, 1988, Reflectance and petrology profile of a partially combusted and coked bituminous coal seam from British Columbia: Fuel, v. 67, p. 1218-1222.Goodarzi, F., T. Gentzis, C. Harrison, and R. Thorsteinsson, 1992, The significance of graptolite reflectance in regional thermal maturity studies, Queen Elizabeth Islands, Arctic Canada: Organic Geochemistry, v. 18, p. 347-357.

Goodarzi, F., T. Gentzis, L.R. Snowdon, R.M. Bustin, S. Feinstein, and M. Labonte, 1993, Effect of mineral matrix and seam thickness on reflectance of vitrinite in high to low volatile bituminous coals: an enigma: Marine and Petroleum Geology, v. 10, p. 162-171.Goodarzi, F., T. Gentzis, L.R. Snowdon, R.M. Bustin, S. Feinstein, and M. Labonte, 1993, Effect of mineral matrix and seam thickness on reflectance of vitrinite in high to low volatile bituminous coals: an enigma: Marine and Petroleum Geology, v. 10, p. 162-171.Goodarzi, F., T. Gentzis, L.R. Snowdon, R.M. Bustin, S. Feinstein, and M. Labonte, 1993, Effect of mineral matrix and seam thickness on reflectance of vitrinite in high to low volatile bituminous coals: an enigma: Marine and Petroleum Geology, v. 10, p. 162-171.Goodarzi, F., T. Gentzis, S. Feinstein, and L. Snowdon, 1988, Effect of maceral subtypes and mineral matter matrix on measured reflectance of subbituminous coals and dispersed organic matter: International Journal of Coal Geology, v. 10, p. 383-398.Goodarzi, F., T. Gentzis, S. Feinstein, and L. Snowdon, 1988, Effect of maceral subtypes and mineral matter matrix on measured reflectance of subbituminous coals and dispersed organic matter: International Journal of Coal Geology, v. 10, p. 383-398.Goodarzi, F., T. Gentzis, S. Feinstein, and L. Snowdon, 1988, Effect of maceral subtypes and mineral matter matrix on measured reflectance of subbituminous coals and dispersed organic matter: International Journal of Coal Geology, v. 10, p. 383-398.Goodman, A.L., A. Busch, G.J. Duffy, J.E. Fitzgerald, K.A.M. Gasem, Y. Gensterblum, B.M. Krooss, J. Levy, E. Ozdemir, Z. Pan, R.L. Robinson, Jr., K. Schroeder, M. Sudibandriyo, and C. White, 2004, An inter-laboratory comparison of CO2 isotherms measured on Argonne premium coal samples: Energy and Fuels, v. 18, p. 1175-1182.Goodman, A.L., A. Busch, G.J. Duffy, J.E. Fitzgerald, K.A.M. Gasem, Y. Gensterblum, B.M. Krooss, J. Levy, E. Ozdemir, Z. Pan, R.L. Robinson, Jr., K. Schroeder, M. Sudibandriyo, and C. White, 2004, An inter-laboratory comparison of CO2 isotherms measured on Argonne premium coal samples: Energy and Fuels, v. 18, p. 1175-1182.Goodman, A.L., A. Busch, R.M. Bustin, L. Chikatamarla, S. Day, G.J. Duffy, J.E. Fitzgerald, K.A.M. Gasem, Y. Gensterblum, C. Hartman, C. Jing, B.M. Krooss, S. Mohammed, T. Pratt, R.L. Robinson, Jr., V. Romanov, R. Sakurovs, K. Schroeder, and C.M. White, 2007, Inter-laboratory comparison II: CO2 isotherms measured on moisture-equilibrated Argonne premium coals at 55°C and up to 15 MPa: International Journal of Coal Geology, v. 72, p. 153-164. (see Yu et al., 2008 for comment)Goodman, A.L., R.N. Favors, M.M. Hill, and J.W. Larsen, 2005, Structure changes in Pittsburgh No. 8 coal caused by sorption of CO2 gas: Energy & Fuels, v. 19, p. 1759-1760.Goolsby, S.M., N.B.S. Reade, and D.K. Murray, 1979, Evaluation of coking coals in Colorado: Colorado Geological Survey, Resource Series 7, 72 p.

Gorbaty, M.L., 1996, Advances and trends in understanding coal structure: Erdöl Erdgas Kohle, v. 112, no. 6, p. 266-267.Gorbaty, M.L., J.W. Larsen, and I. Wender, eds., 1983, Coal science, v. 2: New York, Academic Press, 300 p.

Gorter, J.D., 1984, Source potential of the Horn Valley Siltstone, Amadeus basin: APEA Journal, v. 24, part 1, p. 66-90.

Goscinski, J.S., R.J. Gray, and J.W. Robinson, 1985, A review of American coal quality and its effect on coke reactivity and after reaction strength of cokes, part 1: Journal of Coal Quality, v. 4, no. 1, p. 35-43.Goscinski, J.S., R.J. Gray, and J.W. Robinson, 1985, A review of American coal quality and its effect on coke reactivity and after reaction strength of cokes, part 2: Journal of Coal Quality, v. 4, no. 2, p. 21-29.Gossling, J.M., 1994, Coalbed methane potential of the Hartshorne coals in parts of Haskell, Latimer, LeFlore, McIntosh, and Pittsburg Counties,Oklahoma: Norman, University of Oklahoma, unpublished M.S. thesis, 155 p.

Gould, R.F., ed., 1966, Coal science: Washington, American Chemical Society, Advances in Chemistry Series 55, 743 p.

Goodarzi, F., M.G. Fowler, M. Bustin, and D.M. McKirdy, 1992, Thermal maturity of early Paleozoic sediments as determined by the optical properties of marine-derived organic matter, a review, in M. Schidlowski et al., eds., Early organic evolution: implications for mineral and energy resources: New York, Springer-Verlag, p. 279-295.

Goodarzi, F., S.S. Gandhi, and L.R. Snowdon, 1989, Bitumen in a Lower Proterozoic dolomite hosting Pb-Zn-Cu occurrences, Artillery Lake, Northwest Territories, in Current Research Part C: Geological Survey of Canada, Paper 89-1C, p. 369-376.Goodarzi, F., T. Gentzis, and A.F. Embry, 1989, Organic petrology of two coal-bearing sequences from the Middle to Upper Devonian of Melville Island, Arctic Canada, in Contributions to Canadian coal geoscience: Geological Survey of Canada Paper 89-8, p. 120-130.

Goodarzi, F., T. Gentzis, D. Mossman, and B. Nagy, 1993, Petrography and genesis of organic matter in the paleoproterozoic uraniferous conglomerates of the Elliot Lake region, Ontario, in F. Goodarzi and R.W. Macqueen, eds., Geochemistry and petrology of bitumen with respect to hydrocarbon generation and mineralization: Energy Sources, v. 15, p. 339-357.Goodarzi, F., T. Gentzis, G. Jackson, and R.W. Macqueen, 1993, Optical characteristics of heat-affected bitumens from the Nanisivik mine, N.W. Baffin Island, Arctic Canada, in F. Goodarzi and R.W. Macqueen, eds., Geochemistry and petrology of bitumen with respect to hydrocarbon generation and mineralization: Energy Sources, v. 15, p. 359-376.

Goolsby, S.M., N.B.S. Reade, and L.R. Ladwig, 1980, Coking-coal deposits in Colorado, in L.M. Carter, ed., Proceedings of the fourth symposium on the geology of Rocky Mountain coal–1980: Colorado Geological Survey, Resource Series 10, p. 73-75.

Gorin, E., 1981, Fundamentals of coal liquefaction, in M.A. Elliott, ed., Chemistry of coal utilization, second supplementary volume: New York, John Wiley and Sons, p. 1845-1918.

Goscinski, J.S., J.W. Robinson, and D. Chun, 2014, Megascopic description of coal drill cores, in R.R. Dutcher, ed., Field description of coal: Philadelphia, PA, American Society for Testing and Materials, Special Technical Publication 661, p. 50-57.

Gotz, G., W. Pickel, and M. Wolf, 1995, Petrographic effects on bituminous coals after treatment with sub- and supercritical fluid phases, in J.A. Pajares and J.M.D. Tascon, eds., Coal science, v. 1: New York, Elsevier, Coal Science and Technology 24, p. 295-298.Götz, G., W. Pickel, and M. Wolf, 1995, Petrographic effects on bituminous coals after treatment with sub- and supercritical fluid phases, in J.A. Pajares and J.M.D. Tascon, eds., Coal science: New York, Elsevier, Coal Science and Technology 24, v. 1, p. 295-298.

Graham, R., 1934, Pennsylvanian flora of Illinois as revealed in coal balls. I: Botanical Gazette, v. 95, p. 453-476.Graham, R., 1935, Pennsylvanian flora of Illinois as revealed in coal balls. II: Botanical Gazette, v. 97, p. 156-168.Graham, S.A., and L.A. Williams, 1985, Tectonic, depositional, and diagenetic history of Monterey Formation (Miocene), central San Joaquin basin, California: AAPG Bulletin, v. 69, p. 385-411.Graham, S.A., S. Brassell, A.R. Carroll, X. Xiao, G. Demaison, C.L. McKnight, Y. Liang, J. Chu, and M.S. Hendrix, 1990, Characteristics of selected petroleum source rocks, Xianjiang Uygur autonomous region, northwest China: AAPG Bulletin, v. 74, p. 493-512.Graham, U.M., J.C. Hower, R.F. Rathbone, and M.M. Spears, 1994, Pyrolysis processing characteristics of Kentucky cannel coals: Organic Geochemistry, v. 22, p. 33-37.Grainger, L., and J. Gibson, 1981, Coal utilization: technology, economics and policy: London, Graham and Trotman Ltd., 503 p.Gransden, J.F., J.G. Jorgensen, N. Manery, J.T. Price, and N.J. Ramey, 1991, Applications of microscopy to coke making: International Journal of Coal Geology, v. 19, p. 77-107.Grasby, S.E., H. Sanei, and B. Beauchamp, 2011, Catastrophic dispersion of coal fly ash into oceans during the latest Permian extinction: Nature Geoscience, v. 4, p. 104-107.Grau, R.H., III, and J.C. LaScola, 1984, Methane emissions from U.S. coal mines in 1980: U.S. Bureau of Mines Information Circular 8987, 13 p.Graves, S.L., A.F. Patton, and W.M. Beavers, 1983, Multiple zone coal degasification potential in the Warrior coal field of Alabama: Gulf Coast Association of Geological Societies Transactions, v. 33, p. 275-280.Gray, D., G. Barrass, J. Jezko, and J.R. Kershaw, 1980, Relations between hydroliquefaction behavior and the organic properties of a variety of South African coals: Fuel, v. 59, p. 146-150.

Gray, I., 1987, Reservoir engineering in coal seams: part 1. The physical process of gas storage and movement in coal seams: SPE Reservoir Engineering, v. 2, p. 28-34.

Gray, R.J., 1976, A system of coke petrography: Illinois Mining Institute Proceedings 1976, p. 20-47.Gray, R.J., 1982, A petrographic method of analysis of nonmaceral microstructures in coal: International Journal of Coal Geology, v. 2, p. 79-97.Gray, R.J., 1982, A petrologic method of analysis of nonmaceral microstructures in coal: International Journal of Coal Geology, v. 2, p. 79-97.

Gray, R.J., 1991, Some petrographic applications to coal, coke and carbons: Organic Geochemistry, v. 17, p. 535-555.Gray, R.J., A.H. Rhoades, and D.T. King, 1976, Detection of oxidized coal and the effect of oxidation on the technological properties: Transactions of SME, v. 260, p. 334-341.Gray, R.J., and C.M. Bowling, 1995, Petrographic prediction of coking properties for the Curragh coals of Australia: International Journal of Coal Geology, v. 27, p. 279-298.

Gray, R.J., and K.F. DeVanney, 1986, Coke carbon forms: microscopic classification and industrial applications: International Journal of Coal Geology, v. 6, p. 277-297.Gray, R.J., and N. Schapiro, 1966, Petrographic composition and coking characteristics of Sunnyside coal from Utah: Utah Geological and Mineralogical Survey, Bulletin 80, p. 55-79.Gray, R.J., and P.E. Champagne, 1988, Petrographic characteristics impacting the coal to coke transformation: Ironmaking Conference Proceedings, v. 47, p. 313-324.Gray, R.J., J.S. Goscinski, and R.W. Shoenberger, 1978, Selection of coals for coke making: Joint Conference of Iron and Steel Society and Society of Mining Engineers, Pittsburg, PA, 48 p.Gray, R.J., S.J. Todd, and T.D. Drexler, 1979, Automatic reflectance microscopy of coal: 1979 Ironmaking Conference, v. 38, 16 p.

Graz, Y., C. Di-Giovanni, Y. Copard, F. Laggoun-Défarge, M. Boussafir, E. Lallier-Vergès, P. Baillif, L. Perdereau, and A. Simonneau, 2010, Quantitative palynofacies analysis as a new tool to study transfers of fossil organic matter in recent terrestrial environments: International Journal of Coal Geology, v. 84, p. 49-62.Greb, S.F., 2013, Coal more than a resource: Critical data for understanding a variety of earth-science concepts: International Journal of Coal Geology, v. 118, p. 15-32.Greb, S.F., 2013, Coal more than a resource: Critical data for understanding a variety of earth-science concepts: International Journal of Coal Geology, v. 118, p. 15-32.Greb, S.F., and W.A. DiMichele, eds., 2006, Wetlands through time: Geological Society of America Special Paper 399, 332 p.Greb, S.F., C.F. Eble, and D.R. Chesnut Jr., 2002, Comparison of the eastern and western Kentucky coal fields (Pennsylvanian), USA—why are coal distribution patterns and sulfur contents so different in these coal fields?: International Journal of Coal Geology, v. 50, p. 89-118.Greb, S.F., C.F. Eble, and J.C. Hower, 1996, Coal-bench architecture as a means of understanding regional changes in coal thickness and quality (abstract): AAPG Bulletin, v. 80, p. 1524.

Goulty, N.R., 1995, Review of borehole seismic methods developed for opencast coal exploration, in M.K.G. Whateley and D.A. Spears, eds., European coal geology: London, Geological Society Special Publication 82, p. 159-167.Grady, W.C., C.F. Eble, and S.G. Neuzil, 1993, Brown coal maceral distributions in a modern domed tropical Indonesian peat and a comparison with maceral distributions in Middle Pennsylvanian-age Appalachian bituminous coal beds, in J.C. Cobb and C.B. Cecil, eds., Modern and ancient coal-forming environments: Geological Society of America Special Paper 286, p. 63-82.Grady, W.C., C.F. Eble, and S.G. Neuzil, 1993, Brown coal maceral distributions in a modern domed tropical Indonesian peat and a comparison with maceral distributions in Middle Pennsylvanian-age Appalachian bituminous coal beds, in J.C. Cobb and C.B. Cecil, eds., Modern and ancient coal-forming environments: GSA Special Paper 286, p. 63-82.

Gray, D., G. Barrass, J. Jezko, and J.R. Kershaw, 1980, South African coals and their behavior during liquefaction, in D.D. Whitehurst, ed., Coal liquefaction fundamentals: Washington, D.C., American Chemical Society, Symposium Series 139, p. 35-51.

Gray, I., 1992, Reservoir engineering in coal seams: Part 1 — the physical process of gas storage and movement in coal seams, in Coalbed methane: Society of Petroleum Engineers, Reprint Series 35, p. 7-13.Gray, J., 1965, Extraction techniques, in B. Kummel and D. Raup, eds., Handbook of palaeontological techniques: San Francisco, W.H. Freeman, p. 530-587.

Gray, R.J., 1989, Coal to coke conversion, in H. Marsh, ed., Introduction to carbon science: Boston, Butterworths, p. 285-321.

Gray, R.J., and D.E. Lowenhaupt, 1989, Aging and weathering, in R. Klein and R. Wellek, eds., Sample selection, aging, and reactivity of coal: New York, John Wiley & Sons, p. 255-334.Gray, R.J., and K.C. Krupinski, 1976, Use of microscopic procedures to determine the extent of destruction of agglomerating properties of coal, in C.J. Smith, compiler, Proceedings of the coal agglomeration and conversion symposium: West Virginia Geological and Economic Survey, p. 37-61.

Grayson, J.F., 1975, Relationship of palynomorph translucency to carbon and hydrocarbons in clastic sediments, in B. Alpern, ed., Petrographie de la matiere organique des sediments, relations avec la paleotemperature et le potentiel petrolier: Paris, Centre National de la Recherche Scientifique, p. 261-273.Grayson, J.F., 1981, Microspectrofluorescence and kerogen liquefaction, in J. Brooks, ed., Organic maturation studies and fossil fuel exploration: New York, Academic Press, p. 343-349.

Greb, S.F., C.F. Eble, and J.C. Hower, 2005, Subtle structural influences on coal thickness and distribution: examples from the Lower Broas-Stockton coal (Middle Pennsylvanian), eastern Kentucky coal field, USA, in P.D. Warwick, ed., Coal systems analysis: GSA Special Paper 387, p. 31-50.

Greb, S.F., C.F. Eble, J.C. Hower, and W.M. Andrews, 2002, Multiple-bench architecture and interpretations of original mire phases—examples from the Middle Pennsylvanian of the central Appalachian Basin, USA: International Journal of Coal Geology, v. 49, p. 147-175.

Green, M.S., K.C. Flanegan, and P.C. Gilcrease, 2008, Characterization of a methanogenic consortium enriched from a coalbed methane well in the Powder River Basin, U.S.A.: International Journal of Coal Geology, v. 76, p. 34-45.Gregory, W.A., E.W. Chinn, R. Sadden, and G.F. Hart, 1991, Fluorescence microscopy of particulate organic matter: Sparta Formation and Wilcox Group, south central Louisiana: Organic Geochemistry, v. 17, p. 1-9.Gregory, W.A., E.W. Chinn, R. Sassen, and G.F. Hart, 1991, Fluorescent microscopy of particulate organic matter: Sparta Formation and Wilcox Group, south central Louisiana: Organic Geochemistry, v. 17, p. 1-9.Gregory, W.A., Jr., and G.F. Hart, 1990, Subdivision of Wilcox Group (Sabinian) argillaceous sediments using particulate organic matter: Palynology, v. 14, p. 105-121.Greta, E., S. Dai, and X. Li, 2013, Fluorine in Bulgarian coals: International Journal of Coal Geology, v. 105, p. 16-23.GRI, 1989, Coalbed methane information sources: GRI Quarterly Review of Methane from Coal Seams Technology, v. 7, nos. 1-2, p. 20-26.GRI, 1989, GRI publications on coalbed methane: GRI Quarterly Review of Methane from Coal Seams Technology, v. 7, nos. 1-2, p. 13-19.GRI, 1991, Cherokee basin, Kansas and Oklahoma: Quarterly Review of Methane from Coal Seams Technology, v. 8, no. 2, p. 2.GRI, 1992, Arkoma basin, Oklahoma and Arkansas: Quarterly Review of Methane from Coal Seams Technology, v. 9, nos. 3-4, p. 2.GRI, 1992, Cherokee basin, Kansas and Oklahoma: Quarterly Review of Methane from Coal Seams Technology, v. 9, nos. 3-4, p. 5.GRI, 1993, Western Interior coal region (Arkoma, Cherokee, and Forest City basins): Quarterly Review of Methane from Coal Seams Technology, v. 11, no. 1, p. 43-48.GRI, 1994, Open-hole cavity completions, fracturing, and restimulation: Quarterly Review of Methane from Coal Seams Technology, v. 11, nos. 3-4, 55 p.Griepink, B., A. Scholz, and H.C. Wilkinson, 1989, The production and certification of coal reference materials. Part III: the calorific value of three coal materials: Erdol und Kohle-Erdgas-Petrochemie, v. 42, p. 35-37.Grieve, D.A., 1991, Biaxial vitrinite reflectance in coals of the Elk Valley coalfield, southeastern British Columbia, Canada: International Journal of Coal Geology, v. 19, p. 185-200.Grieve, D.A., and F. Goodarzi, 1993, Trace elements in coal samples from active mines in the Foreland Belt, British Columbia, Canada: International Journal of Coal Geology, v. 24, p. 259-280.Grigore, M., R. Sakurovs, D. French, and V. Sahajwalla, 2008, Mineral matter in coals and their reactions during coking: International Journal of Coal Geology, v. 76, p. 301-308.Grigore, M., R. Sakurovs, D. French, and V. Sahajwalla, 2008, Mineral matter in coals and their reactions during coking: International Journal of Coal Geology, v. 76, p. 301-308.Grigore, M., R. Sakurovs, D. French, and V. Sahajwalla, 2008, Mineral reactions during coke gasification with carbon dioxide: International Journal of Coal Geology, v. 75, p. 213-224.Grigore, M., R. Sakurovs, D. French, and V. Sahajwalla, 2012, Properties and CO2 reactivity of the inert and reactive maceral-derived components in cokes: International Journal of Coal Geology, v. 98, p. 1-9.Grimm, R.P., K.A. Eriksson, N. Ripepi, C. Eble, and S.F. Greb, 2012, Seal evaluation and confinement screening criteria for beneficial carbon dioxide storage with enhanced coal bed methane recovery in the Pocahonta Basin, Virginia: International Journal of Coal Geology, v. 90-91, p. 110-125.Grimm, R.P., K.A. Eriksson, N. Ripepi, C. Eble, and S.F. Greb, 2012, Seal evaluation and confinement screening criteria for beneficial carbon dioxide storage with enhanced coal bed methane recovery in the Pocahonta Basin, Virginia: International Journal of Coal Geology, v. 90-91, p. 110-125.Grina, J.A., R.W. Shoenberger, and R.J. VanPelt, 1981, Coke making improvement programs at US Steel: Society of Mining Engineers at AIME, Transactions v. 270, p. 1873-1878.Grint, A., and H. Marsh, 1981, Carbonisation of coal blends: mesophase formation and coke properties: Fuel, v. 60, p. 1115-1120.Griswold, T.B., J.C. Hower, and J.C. Cobb, 1990, Impact of coal quality variations on utilization of the Springfield (western Kentucky no. 9) coal bed: Journal of Coal Quality, v. 9, no. 4, p. 113-119.Griswold, T.B., J.C. Hower, and J.C. Cobb, 1990, Impact of coal quality variations on utilization of the Springfield (western Kentucky no. 9) coal bed: Journal of Coal Quality, v. 9, p. 113-119.Grobe, M., J.C. Pashin, and R.L. Dodge, eds., 2010, Carbon dioxide sequestration in geological media—state of the science: AAPG Studies in Geology 59, 716 p.

Groshong, R. H., Jr., M. H. Cox, J. C. Pashin, and M. R. McIntyre, 2003, Relationship between gas and water production and structure in southeastern Deerlick Creek coalbed methane field, Black Warrior basin, Alabama: Tuscaloosa, Alabama, University of Alabama College of Continuing Studies, 2003 International Coalbed Methane Symposium Proceedings, Paper 0306, 12 p.Grosjean, E., P. Adam, J. Connan, and P. Albrecht, 2004, Effects of weathering on nickel and vanadyl prophyrins of a Lower Toarcian shale of the Paris basin: Geochimica et Cosmochimica Acta, v. 68, p. 789-804.Gross, J.S., S.A. Thompson, B.L. Claxton, and M.B. Carr, 1995, Reservoir distribution and exploration potential of the Spiro sandstone in the Choctaw trend, Arkoma basin, Oklahoma and Arkansas: AAPG Bulletin, v. 79, p. 159-185.Grossman, S.L., and H. Cohen, 1998, Emission of toxic explosive and fire hazardous gases in coal piles stored under atmospheric conditions (part 1 of a 2 part article): Energeia, v. 9, no. 3, p. 1, 4-5. (spontaneous combustion)Grossman, S.L., S. David, I. Wegener, W. Wanzl, and H. Cohen, 1996, Explosion risks of bituminous coals in contact with air: Erdöl Erdgas Kohle, v. 112, p. 322-324. (spontaneous combustion)

Groth, P.K.H., 1994, Variation of vitrinite reflectance data due to laboratory slide-making methods (abstract): AAPG Annual Convention, Abstracts, p. 159.

Grubb, W.A., 2003, ‘Purpose-fit’ technologies key part of equation for CBM production economics: American Oil & Gas Reporter, v. 46, no. 1, p. 131-135.

Greb, S.F., C.F. Eble, D.R. Chesnut, Jr., T.L. Phillips, and J.C. Hower, 1999, An in situ occurrence of coal balls in the Amburgy coal bed, Pikeville Formation (Duckmantian), central Appalachian basin, USA: Palaios, v. 14, p. 432-450.

Greb, S.F., D.R. Chesnut, Jr., and C.F. Eble, 2004, Temporal changes in coal-bearing depositional sequences (Lower and Middle Pennsylvanian) of the Central Appalachian Basin, U.S.A., in J.C. Pashin and R.A. Gastaldo, eds., Sequence stratigraphy, paleoclimate, and tectonics of coal-bearing strata: AAPG Studies in Geology 51, p. 89-120.Greb, S.F., W.A. DiMichele, and R.A. Gastaldo, 2006, Evolution and importance of wetlands in earth history, in S.F. Greb and W.A. DiMichele, eds., Wetlands through time: Geological Society of America Special Paper 399, p. 1-40.Greb, S.F., W.M. Andrews, C.F. Eble, W. DiMichele, C.B. Cecil, and J.C. Hower, 2003, Desmoinesian coal beds of the Eastern Interior and surrounding basins: the largest tropical peat mires in Earth history, in M.A. Chan and A.W. Archer, eds., Extreme depositional environments: Mega end members in geologic time: Geological Society of America Special Paper 370, p. 127-150.

Groppo, J., T. Robl, and J.C. Hower, 2004, The beneficiation of coal combustion ash, in R. Gieré and P. Stille, eds., Energy, waste and the environment: a geochemical perspective: London, Geological Society, Special Publication 236, p. 247-262.

Grosspietsch, K.H., H.B. Lunge, G. Dauwels, A. Ferstl, T. Karjalahti, P. Negro, B.V. Veldon, and F. Willmers, 2000, Coke quality requirements by European blast furnace operators on the turn of the millennium: 4 th European Coke and Ironmaking Congress, ATS, Paris, Proceedings, p. 2-11.

Grout, M.A., 1991, Cleats in coalbeds of southern Piceance basin, Colorado - correlation with regional and local fracture sets in associated clastic rocks, in S.D. Schwochow, D.K. Murray, and M.F. Fahy, eds., Coalbed methane of western North America: Denver, Rocky Mountain Association of Geologists, p. 35-47.

Gruber, W., and R.F. Sachsenhofer, 2001, Coal deposition in the Noric Depression (eastern Alps): raised and low-lying mires in Miocene pull-apart basins: International Journal of Coal Geology, v. 48, p. 89-114.Gruszkiewicz, M.S., M.T. Naney, J.G. Blencoe, D.R. Cole, J.C. Pashin, and R.E. Carroll, 2009, Adsorption kinetics of CO2, CH4, and their equimolar mixture on coal from the Black Warrior Basin, west-central Alabama: International Journal of Coal Geology, v. 77, p. 23-33.

Guckert, K.D., and D.J. Mossman, 2003, Pennsylvanian coal and associated bitumen at Johnson Mills, Shepody Bay, New Brunswick, Canada: International Journal of Coal Geology, v. 53, p. 137-152.Guedes, A., B. Valentim, A.C. Prieto, A. Sanz, D. Flores, and F. Noronha, 2008, Characterization of fly ash from a power plant and surroundings by micro-Raman spectroscopy: International Journal of Coal Geology, v. 73, p. 359-370.Guedes, A., B. Valentim, A.C. Prieto, S. Rodrigues, and F. Noronha, 2010, Micro-Raman spectroscopy of collotelinite, fusinite and macrinite: International Journal of Coal Geology, v. 83, p. 415-422.

Guennel, G.K., and R.C. Neavel, 1959, Paper coal in Indiana: Science, v. 129, p. 1671-1672.Guerrero, A., M.A. Diez, and A.G. Borrego, 2013, Effect of volatile matter release on optical properties of macerals from different rank coals: Fuel, v. 114, p. 21-30.Guerrero, A., M.A. Diez, and A.G. Borrego, 2013, Effect of volatile matter release on optical properties of macerals from different rank coals: Fuel, v. 114, p. 21-30.Gunter, W.D., S. Wong, D.B. Cheel, and G. Sjostrom, 1998, Large CO2 sinks: their role in the mitigation of greenhouse gases from international, national (Canadian) and provincial (Alberta) perspective: Applied Energy, v. 61, p. 209-227.Gunter, W.D., T. Gentzis, B.A. Rotternfusser, and R.J.H. Richardson, 1997, Deep coalbed methane in Alberta, Canada: a fuel resource with the potential of zero greenhouse emissions: Energy Conversion and Management, v. 38S, p. S217-S222.Guo, H., J. Lin, Y. Yang, and Y. Liu, 2014, Effect of minerals on the self-heating retorting of oil shale: Self-heating effect and shale-oil production: Fuel, v. 118, p. 186-193.Guo, H., R. Liu, Z. Yu, H. Zhang, J. Yun, Y. Li, X. Lu, and J. Pan, 2012, Pyrosequencing reveals the dominance of methylotrophic methanogenesis in a coal bed methane reservoir associated with eastern Ordos Basin in China: International Journal of Coal Geology, v. 93, p. 56-61.Guo, Y., and R.M. Bustin, 1998, FTIR spectroscopy and reflectance of modern charcoals and fungal decayed woods: implications for studies of inertinite in coals: International Journal of Coal Geology, v. 37, p. 29-53.Guo, Y., and R.M. Bustin, 1998, Micro-FTIR spectroscopy of liptinite macerals in coal: International Journal of Coal Geology, v. 36, p. 259-275.Guo, Y., J.J. Renton, and J.H. Penn, 1996, FTIR microspectroscopy of particular liptinite-rich, Late Permian coals from southern China: International Journal of Coal Geology, v. 29, p. 187-197.Guoyi, H., L. Jin, S. Xiuqin, and H. Zhongxi, 2010, The origin of natural gas and the hydrocarbon charging history of the Yulin gas field in the Ordos Basin, China: International Journal of Coal Geology, v. 81, p. 381-391.Guoyi, H., Z. Shuichang, L. Jin, L. Jijun, and H. Zhongxi, 2010, The origin of natural gas in the Hutubi gas field, southern Junggar foreland sub-basin, NW China: International Journal of Coal Geology, v. 84, p. 301-310.Gupta, R., T. Wall, and L. Baxter, eds., 1999, The impact of mineral impurities in solid fuel combustion: Norwell, MA, Kluwer Academic/Plenum Publishers, 788 p.Gupta, S., F. Shen, W.-J. Lee, and G. O’Brien, 2012, Improving coke strength prediction using automated coal petrography: Fuel, v. 94, p. 368-373.Gurba, L.W., and C.R. Ward, 1998, Vitrinite reflectance anomalies in high-volatile bituminous coals of the Gunnedah basin, New South Wales, Australia: International Journal of Coal Geology, v. 36, p. 111-140.Gurba, L.W., and C.R. Ward, 1998, Vitrinite reflectance anomalies in high-volatile bituminous coals of the Gunnedah basin, New South Wales, Australia: International Journal of Coal Geology, v. 36, p. 111-140.Gurba, L.W., and C.R. Ward, 1998, Vitrinite reflectance anomalies in the high-volatile bituminous coals of the Gunnedah Basin, New South Wales, Australia: International Journal of Coal Geology, v. 36, p. 111-140.

Gurba, L.W., and C.R. Ward, 2000, Elemental composition of coal macerals in relation to vitrinite reflectance, Gunnedah Basin, Australia, as determined by electron microprobe analysis: International Journal of Coal Geology, v. 44, p. 127-147.Gurba, L.W., and C.R. Ward, 2000, Elemental composition of coal macerals in relation to vitrinite reflectance, Gunnedah basin, Australia, as determined by electron microprobe analysis: International Journal of Coal Geology, v. 44, p. 127-147. (suppression caused by high carbon content)Gurba, L.W., and C.R. Weber, 2000, Coal petrology and coalbed methane occurrence in the Gloucester basin, NSW, Australia (abstract): TSOP Abstracts and Program, v. 17, p. 47.Gurba, L.W., and C.R. Weber, 2001, Effects of igneous intrusions on coalbed methane potential, Gunnedah basin, Australia: International Journal of Coal Geology, v. 46, p. 113-131.Gurba, L.W., and C.R. Weber, 2001, The relevance of coal petrology to coalbed methane evaluation, using the Gloucester basin, Australia as a model: Tuscaloosa, Alabama, Proceedings, International Coalbed Methane Symposium, Paper 147, p. 371-382.Gürdal, G., 2008, Geochemistry of trace elements in Çan coal (Miocene) Çanakkale, Turkey: International Journal of Coal Geology, v. 74, p. 28-40.Gürdal, G., 2011, Abundances and modes of occurrence of trace elements in the Çan coals (Miocene), Çanakkale–Turkey: International Journal of Coal Geology, v. 87, p. 157-173.Gürdal, G., and M. Bozcu, 2011, Petrographic characteristics and depositional environment of Miocene Çan coals, Çanakkale-Turkey: International Journal of Coal Geology, v. 85, p. 143-160.Gürdal, G., and M.N. Yalçin, 2000, Gas adsorption capacity of Carboniferous coals in the Zonguldak basin (NW Turkey) and its controlling factors: Fuel, v. 79, p. 1913-1924.Gürdal, G., and M.N. Yalçin, 2001, Pore volume and surface area of the Carboniferous coals from the Zonguldak basin (NW Turkey) and their variations with rank and maceral composition: International Journal of Coal Geology, v. 48, p. 133-144.Guthrie, B., 1938, Studies of certain properties of oil shale and shale oil: U.S. Bureau of Mines Bulletin 415, 159 p.Gutjahr, C.C.M., 1983, Introduction to incident-light microscopy of oil and gas source rocks: Geologie en Mijnbouw, v. 62, p. 417-425.

Grzybek, I., 1999, Residual gas content of coal in the light of observations from the Upper Silesian coal basin, Poland, in M. Mastalerz, M. Glikson, and S.D. Golding, eds., Coalbed methane: scientific, environmental and economic evaluation: Boston, Kluwer Academic Publishers, p. 139-153.Gu, Z., and M. Deo, 2009, Applicability of carbon dioxide enhanced oil recovery to reservoirs in the Uinta Basin, Utah: Utah Geological Survey, OFR-538, CD-ROM, 13 p. http://ugspub.nr.utah.gov/publications/open_file_reports/OFR-538.pdf

Guennel, G.K., 1981, Oil from pollen and spores, in J. Brooks, ed., Organic maturation studies and fossil fuel exploration: New York, Academic Press, p. 308-318.Guennel, G.K., 1981, Oil from pollen and spores, in J. Brooks, ed., Organic maturation studies and fossil fuel exploration: San Francisco, Academic Press, p. 303-318.

Gurba, L.W., and C.R. Ward, 1999, The influence of depositional and maturation factors on the three-dimensional distribution of coal rank indicators and hydrocarbon source potential in the Gunnedah basin, New South Wales, in M. Mastalerz, M. Glikson, and S.D. Golding, eds., Coalbed methane: scientific, environmental and economic evaluation: Boston, Kluwer Academic Publishers, p. 493-515.

Guy-Ohlson, D., 1996, Prasinophycean algae, in J. Jansonius and D.C. McGregor, eds., Palynology: principles and applications: American Association of Stratigraphic Palynologists, v. 1, p. 181-189.Gy, P.M., 1989, Preparation of homogeneous coal samples: an analysis of the homogeneity/heterogeneity concept, in R. Klein and R. Wellek, eds., Sample selection, aging, and reactivity of coal: New York, John Wiley & Sons Interscience, p. 57-99.

Gysi, A.P., and A. Stefánsson, 2012, CO2-water–basalt interaction. Low temperature experiments and implications for CO2 sequestration into basalts: Geochimica et Cosmochimica Acta, v. 81, p. 129-152.

Hackley, P.A., and M. Martinez, 2007, Organic petrology of Paleocene Marcelina Formation coals, Paso Diablo mine, western Venezuela: Tectonic controls on coal type: International Journal of Coal Geology, v. 71, p. 505-526.

Hackley, P.C., and P.D. Warwick, 2005, Organic petrography of coals from a coalbed methane test well, Ouachita Parish, Louisiana: USGS Open-File Report 2005-1134, 20 p.Hackley, P.C., E.H. Guevara, T.F. Hentz, and R.W. Hook, 2009, Thermal maturity and organic composition of Pennsylvanian coals and carbonaceous shales, north-central Texas: Implications for coalbed gas potential: International Journal of Coal Geology, v. 77, p. 294-309.Hackley, P.C., J.R. SanFilipo, G.P. Azizi, P.A. Davis, and S.W. Staratt, 2010, Organic petrology of subbituminous carbonaceous shale samples from Chalāw, Kabul Province, Afghanistan: considerations for paleoenvironment and energy resource potential: International Journal of Coal Geology, v. 81, p. 269-280.Hackley, P.C., P.D. Warwick, and F.C. Breland Jr., 2007, Organic petrology and coalbed gas content, Wilcox Group (Paleocene-Eocene), northern Louisiana: International Journal of Coal Geology, v. 71, p. 54-71.Hackley, P.C., P.D. Warwick, R.W. Hook, H. Alimi, M. Mastalerz, and S.M. Swanson, 2012, Organic geochemistry and petrology of subsurface Paleocene-Eocene Wilcox and Claiborne Group coal beds, Zavala County, Maverick Basin, Texas, USA: Organic Geochemistry, v. 46, p. 137-153.Hackley, P.C., R.T. Ryder, M.H. Trippi, and H. Alimi, 2013, Thermal maturity of northern Appalachian Basin Devonian shales: Insights from sterane and terpane biomarkers: Fuel, v. 106, p. 455-462.Hackley, P.C., R.T. Ryder, M.H. Trippi, and H. Alimi, 2013, Thermal maturity of northern Appalachian Basin Devonian shales: Insights from sterane and terpane biomarkers: Fuel, v. 106, p. 455-462.Hacquebard, P. A., and Donaldson, J. R., 1969, Carboniferous coal deposition associated with floodplain and limnic environments in Nova Scotia: Geological Society of America Special Paper 114, p. 143-191.Hacquebard, P. A., and Donaldson, J. R., 1969, Carboniferous coal deposition associated with floodplain and limnic environments in Nova Scotia: Geological Society of America Special Paper 114, p. 143-191.

Hacquebard, P.A., 1952, Opaque matter in coal: Economic Geology, v. 47, p. 494-516.Hacquebard, P.A., 1993, Petrology and facies studies of the Carboniferous coals at Mabou mines and Inverness in comparison with those of the Port Hood, St. Rose and Sydney coalfields of Cape Breton Island, Nova Scotia, Canada: International Journal of Coal Geology, v. 24, p. 7-46.Hacquebard, P.A., 2002, Potential coalbed methane resources in Atlantic Canada: International Journal of Coal Geology, v. 52, p. 3-28.Hagelskamp, H.H.B., and C.P. Snyman, 1988, On the origin of low-reflecting inertinites in coals from the Highveld coalfield, South Africa: Fuel, v. 67, p. 307-313.Hagemann, H., and A. Hollerbach, 1981, Spectral fluorometric analysis of extracts a new method for the determination of the degree of maturity of organic matter in sedimentary rocks: Bulletin Des Centres De Recherchese Exploration-Production Elf-Aquitaine, v. 5, no. 2, p. 635-650.Hagemann, H.V., and A. Hollerbach, 1986, The fluorescence behaviour of crude oils with respect to their thermal maturation and degradation: Organic Geochemistry, v. 10, p. 473-480.

Hagemann, H.W., 1988, Microfluorometry of films of extracted coals of a coalification series: Zeiss Information, v. 29, no. 99, p. 40-43.

Hagemann, H.W., 1993, Organic petrology, recent developments and state of the art: 12th International Congress of Stratigraphy and Geology of the Carboniferous and Permian, Comptes Rendus, v. 1, p. 61-82.

Hagemann, H.W., and J. Dehmer, 1991, Spectrophotometric lightness and chromaticity measurements on absorbing peat and brown coal surfaces: part I – method and evaluation: International Journal of Coal Geology, v. 19, p. 163-183.Hagemann, H.W., and M. Wolf, 1989, Paleoenvironments of lacustrine coals—the occurrence of algae in humic coals: International Journal of Coal Geology, v. 12, p. 511-522.

Hagermann, R., K.J. Hüttinger, J.F. Lambertz, and L. Schrader, 1990, Kinetic studies on gasification of Rheinische brown coal: influence of pressure, temperature, and mineral matter: Erdöl und Kohle-Erdgas-Petrochemie, v. 43, no. 4, p. 143-144.Hagler, C., and N.P. Boyaci, 2010, New hydraulic lift system overcomes beam pump challenges in CBM wells: World Oil, v. 231, no. 10, p. 77-82.

Hakimi, M.H., W.H. Abdullah, F.L. Alias, M.H. Azhar, and Y.M. Makeen, 2013, Organic petrographic characteristics of Tertiary (Oligocene-Miocene) coals from eastern Malaysia: Rank and evidence for petroleum generation: International Journal of Coal Geology, v. 120, p. 71-81.Hakimi, M.H., W.H. Abdullah, S.-G. Sia, and Y.M. Makeen, 2013, Organic geochemical and petrographic characteristics of Tertiary coals in the northwest Sarawak, Malaysia: Implications for palaeoenvironmental conditions and hydrocarbon generation potential: Marine and Petroleum Geology, v. 48, p. 31-46.Hakimi, M.H., W.H. Abdullah, S.-G. Sia, and Y.M. Makeen, 2013, Organic geochemical and petrographic characteristics of Tertiary coals in the northwest Sarawak, Malaysia: Implications for palaeoenvironmental conditions and hydrocarbon generation potential: Marine and Petroleum Geology, v. 48, p. 31-46.Ham, W.E., 1956, Asphaltite in the Ouachita Mountains: Oklahoma Geological Survey, Mineral Report 30, 12 p.Hamilton, D.S., and N.Z. Tadros, 1994, Utility of coal seams as genetic stratigraphic sequence boundaries in nonmarine basins: an example from the Gunnedah basin, Australia: AAPG Bulletin, v. 78, p. 267-286. (discussion and reply, v. 79, p. 1179-1182)Hamilton, S.K., J.S. Esterle, and S.D. Golding, 2012, Geological interpretation of gas content trends, Walloon Subgroup, eastern Surat Basin, Queensland, Australia: International Journal of Coal Geology, v. 101, p. 21-35.Hamilton, S.K., S.D. Golding, K.A. Baublys, and J.S. Esterle, 2014, Stable isotopic and molecular composition of desorbed coal seam gases from the Walloon Subgroup, eastern Surat Basin, Australia: International Journal of Coal Geology, v. 122, p. 21-36.Hámor-Vidó, M., 2004, Coal facies studies in Hungary: a historical review: International Journal of Coal Geology, v. 58, p. 91-97.

Habib, D., Y. Eshet, and R. Van Pelt, 1994, Palynology of sedimentary cycles, in A. Traverse, ed., Sedimentation of organic particles: Cambridge University Press, p. 311-335.Habib, D., Y. Eshet, and R. van Pelt, 1994, Palynology of sedimentary cycles, in A. Traverse, ed., Sedimentation of organic particles: Cambridge University Press, p. 311-335. (fecal origin of AOM [bituminite])

Hackley, P.C., A.M. Bove, F.T. Dulong, M.D. Lewan, and B.J. Valentine, 2013, Reevaluation of vitrinite reflectance suppression through hydrous pyrolysis experiments (abstract): 65 th Annual Meeting of the International Committee for Coal and Organic Petrology, Program & Abstract Book, p. 32-33.Hackley, P.C., and J.J. Kolak, 2008, Petrographic and vitrinite reflectance analyses of a suite of high volatile bituminous coal samples from the United States and Venezuela: U.S. Geological Survey Open-File Report 2008-1230, 39 p. http://pubs.usgs.gov/of/2008/1230/ofr2008-1230.pdf

Hacquebard, P.A., 1950, The nomenclature and classification of coal petrography, in Conference on the origin and constitution of coal (v.1): Nova Scotia Department of Mines, p. 8-48.

Hagemann, H.W., 1974, Petrographische und palynologische untersuchung der organischen substanz (kerogen) in den Liassischen sedimenten Luxemburgs, in B. Tissot and F. Bienner, eds., Advances in organic geochemistry 1973: Paris, Editions Technip, p. 29-37.

Hagemann, H.W., 1993, Organic petrology, recent developments and state of the art: 12 th International Congress of Stratigraphy and Geology of the Carboniferous and Permian, Comptes Rendus, v. 1, p. 61-82.

Hagemann, H.W., and A. Hollerbach, 1983, The spectral fluorometric analyses of the soluble organic matter applied to hydrocarbon source rock evaluation, in M. Bjoroy and others, eds., Advances in Organic Geochemistry 1981: New York, John Wiley & Sons Ltd., p. 72-75.

Hagemann, H.W., and W. Pickel, 1991, Characteristics of Upper Cretaceous coals from Enugu (Nigeria) related to bitumen generation and mobilization, in P.K. Mukhopadhyay, M.G. Fowler, and W.G. Dow, eds., Selected papers from the symposium on coal and terrestrial organic matter as a source rock for petroleum: Organic Geochemistry, v. 17, p. 839-847.

Haigh and I.H. Edwards, 1982, Computer processing of geophysical logging data in coal deposits, in C.W. Mallett, ed., Coal resources: origin, exploration and utilization in Australia, Proceedings: Geological Society of Australia Coal Group, Symposium, p. 364-380.

Hámor-Vidó, M., and T. Hámor, 2007, Sulphur and carbon isotopic composition of power supply coals in the Pannonian Basin, Hungary: International Journal of Coal Geology, v. 71, p. 425-447.

Han, F., A. Busch, B.M. Krooss, Z. Liu, and J. Yang, 2013, CH4 and CO2 sorption isotherms and kinetics for different size fractions of two coals: Fuel, v. 108, p. 137-142.Han, F., A. Busch, N. van Wageningen, J. Yang, Z. Liu, and B.M. Krooss, 2010, Experimental study of gas and water transport processes in the inter-cleat (matrix) system of coal: anthracite from Qinshui Basin, China: International Journal of Coal Geology, v. 81, p. 128-138.Han, F., A. Busch, N. van Wageningen, J. Yang, Z. Liu, and B.M. Krooss, 2010, Experimental study of gas and water transport processes in the inter-cleat (matrix) system of coal: anthracite from Qinshui Basin, China: International Journal of Coal Geology, v. 81, p. 128-138.Han, W., H. Jin, and R. Lin, 2011, A novel power generation system based on moderate conversion of chemical energy of coal and natural gas: Fuel, v. 90, p. 263-271.Han, X., I. Kulaots, X. Jiang, and E.M. Suuberg, 2014, Review of oil shale semicoke and its combustion utilization: Fuel, v. 126, p. 143-161.Han, Z., and M.A. Kruge, 1999, Chemistry of maceral and groundmass density fractions of torbanite and cannel coal: Organic Geochemistry, v. 30, p. 1381-1401.Han, Z., and M.A. Kruge, 1999, Classification of torbanite and cannel coal. II. Insights from pyrolysis-GC/MS and multivariate statistical analysis: International Journal of Coal Geology, v. 38, p. 203-218.Han, Z., J.C. Crelling, and Y. Zhou, 1993, Fluorescence intensity and alteration of coal macerals and their relation to coalification: Organic Geochemistry, v. 20, p. 677-685.Han, Z., M.A. Kruge, J.C. Crelling, and B.A. Stankiewicz, 1994, Organic geochemical characterization of the density fractions of a Permian torbanite: Organic Geochemistry, v. 21, p. 39-50.Han, Z., M.A. Kruge, J.C. Crelling, and D.F. Bensley, 1999, Classification of torbanite and cannel coal. I. Insights from petrographic analysis of density fractions: International Journal of Coal Geology, v. 38, p. 181-202.Han, Z., Q. Yang, and Z. Pang, 2001, Artificial maturation study of a humic coal and a torbanite: International Journal of Coal Geology, v. 46, p. 133-143.

Hansen, Y., P.J. Notten, and J.G. Petrie, 2002, The environmental impact of ash management in coal-based power generation: Applied Geochemistry, v. 17, p. 1131-1141.Hao, F., and J. Chen, 1992, The cause and mechanism of vitrinite reflectance anomalies: Journal of Petroleum Geology, v. 15, p. 419-434.Hao, F., and J. Chen, 1992, The cause and mechanism of vitrinite reflectance anomalies: Journal of Petroleum Geology, v. 15, p. 419-434.Hao, F., and J. Chen, 1992, The cause and mechanism of vitrinite reflectance anomalies: Journal of Petroleum Geology, v. 15, p. 419-434.Hao, F., H. Zou, Z. Gong, S. Yang, and Z. Zeng, 2007, Hierarchies of overpressure retardation of organic matter maturation: case studies from petroleum basins in China: AAPG Bulletin, v. 91, p. 1467-1498.Hao, F., Y. Sun, S. Li, and Q. Zhang, 1995, Overpressure retardation of organic matter and petroleum generation: a case study from the Yinggehai and Qiongdongan basins, south China sea: AAPG Bulletin, v. 79, p. 551-562.Hao, F., Y. Sun, S. Li, and Q. Zhang, 1995, Overpressure retardation of organic matter and petroleum generation: a case study from the Yinggehai and Qiongdongan basins, south China sea: AAPG Bulletin, v. 79, p. 551-562.Haq, B.U., and A. Boersma, eds., 1978, Introduction to marine micropaleontology: New York, Elsevier, 376 p.

Harpalani, S., and G. Chen, 1993, Gas slippage and matrix shrinkage effects on coal permeability: Tuscaloosa, Alabama, Proceedings of the 1993 International Coalbed Methane Symposium, paper 9325, p. 285-294.Harpalani, S., and G. Chen, 1997, Influence of gas production induced volumetric strain on permeability of coal: Geotechnical and Geological Engineering, v. 15, p. 303-325.Harpalani, S., and R. Schraufnagel, 1990, Shrinkage of coal matrix with release of gas and its impact on permeability of coal: Fuel, v. 69, p. 551-556.Harpalani, S., and X. Zhao, 1989, An investigation of the effect of gas desorption on coal permeability: Proceedings of the 1989 Coalbed Methane Symposium, paper 8923, p. 57-64.Harpalani, S., and X. Zhao, 1991, Microstructure of coal and its influence on flow of gas: Energy Sources, v. 13, p. 229-242.Harpalani, S., and X. Zhao, 1991, Microstructure of coal and its influence on flow of gas: Energy Sources, v. 13, p. 229-242.Harper, D., 1991, Coalbed methane in Indiana: Indiana Geological Survey Occasional Paper 56, 18 p.Harper, J.A., 2004, Practical uses for air pollution—carbon dioxide: Pennsylvania Geology, v. 34, no. 2, p. 2-9.Harper, J.A., 2013, Potential for CO2-enhanced oil and gas recovery, southwestern Pennsylvania: Pennsylvania Geology, v. 42, no. 4, p. 3-13.Harris, L.A., and C.S. Yost, 1976, Transmission electron microscope observation of porosity in coal: Fuel, v. 55, p. 233-236.Harris, L.A., and C.S. Yust, 1976, Transmission electron microscope observations of porosity in coal: Fuel, v. 55, p. 233-236.Harris, L.A., C.S. Yust, and R.S. Crouse, 1977, Direct determination of pyretic and organic sulphur by combined coal petrography and microprobe analysis (CPMA)—a feasibility study: Fuel, v. 56, p. 456-457.Harris, L.A., H.E. Barrett, and O.C. Kopp, 1981, Elemental concentrations and their distribution in two bituminous coals of different paleoenvironments: International Journal of Coal Geology, v. 1, p. 175-193.

Harris, L.A., T. Rose, L. Derose, and J. Greene, 1977, Quantitative analysis of pyrite in coal by optical image techniques: Economic Geology, v. 72, p. 695-697.

Harris, S.H., R.L. Smith, and C.E. Barker, 2008, Microbial and chemical factors influencing methane production in laboratory incubations of low-rank subsurface coals: International Journal of Coal Geology, v. 76, p. 46-51.

Hámor-Vidó, M., T. Hofmann, and L. Albert, 2010, In situ preservation and paleoenvironmental assessment of Taxodiacea fossil trees in the Bükkalja Lignite Formation, Bükkábrány open cast mine, Hungary: International Journal of Coal Geology, v. 81, p. 203-210.

Haney, D.C., and J.C. Cobb, 1993, Coal-resource investigations for Kentucky: traditional versus coal-availability investigations: 12 th International Congress of Stratigraphy and Geology of the Carboniferous and Permian, Comptes Rendus, v. 1, p. 231-238.

Hara, Y., D. Mikuni, H. Yamanoto, and H. Yamanaki, 1980, The assessment of coke quality with particular emphasis on sampling technique, in W.K. Lu, ed., Blast furnace coke-quality, cause, and effect: McMaster University, Canada, p. 4-1 to 4-38.Harpalani, S., and G. Chen, 1992, Effect of gas production on porosity and permeability of coal, in B.B. Beamish, and P.D. Gamson, eds., Symposium on coalbed methane: Townsville, Australia, v. 4, p. 67.

Harris, L.A., O.C. Kopp, and R.S. Crouse, 1982, The application of scanning electron microscopy and ultraviolet fluorescence to a study of Chattanooga Shale specimens, in K.F.J. Heinrich, ed., Microbeam analysis – 1982: San Francisco, San Francisco Press, Inc., p. 465-468.

Harris, N.B., and K.E. Peters, 2012, Analyzing thermal histories of sedimentary basins: Methods and case studies—introduction, in N.B. Harris and K.E. Peters, eds., Analyzing the thermal history of sedimentary basins: Methods and case studies: SEPM Special Publication 103, p. 1-4.

Harrison, C.H., 1991, Electron microprobe analysis of coal macerals: Organic Geochemistry, v. 17, p. 439-449.Harrison, J.A., 1962, Coal petrography applied to coking problems: Illinois State Geological Survey Reprint Series 1962 O, p. 18-44.Harrison, J.A., 1963, Application of coal petrography to coal preparation: SME Transactions of AIME, p. 346-357.Harrison, J.A., 1965, Effect of moisture content on reflectance value of coals: Fuel, v. 44, p. 225-228.Harrison, J.A., and J. Thomas, Jr., 1966, Relation between moisture content, reflectance values and internal surface area of coal: Fuel, v. 45, p. 501-503.Harrison, J.A., H.W. Jackman, and J.A. Simon, 1964, Predicting coke stability from petrographic analysis of Illinois coals: Illinois State Geological Survey Circular 366, 20 p.Harrison, S.M., T. Gentzis, and M. Payne, 2006, Hydraulic, water quality, and isotopic characterization of Late Cretaceous-Tertiary Ardley coal waters in a key test-well, Pembina-Warburg exploration area, Alberta, Canada: Bulletin of Canadian Petroleum Geology, v. 54, p. 238-260.Harrison, W.B., III, G.M. Grammer, and D.A. Barnes, 2009, Reservoir characteristics of the Bass Islands dolomite in Otsego County, Michigan: Results for a saline reservoir CO2 sequestration demonstration: Environmental Geosciences, v. 16, no. 3, p. 139-151.Hart, G.F., 1986, Origin and classification of organic matter in clastic systems: Palynology, v. 10, p. 1-23.

Hartgers, W.A., J.S. Sinninghe Damste, J.W. De Leeuw, Y. Ling, and J.C. Crelling, 1995, The influence of mineral matter on the separation of amorphous marine kerogens using density gradient centrifugation: Organic Geochemistry, v. 23, p. 777-784.

Hartley, A.J., 1993, A depositional model for the mid-Westphalian A to late Westphalian B coal measures of South Wales: Journal of the Geological Society, London, v. 150, p. 1121-1136.Hartmann-Stroup, C., 1987, The effect of organic matter type and organic carbon content on Rock-Eval hydrogen index in oil shales and source rocks: Organic Geochemistry, v. 11, p. 351-369.Hartman-Stroup, C., 1987, The effect of organic matter type and organic carbon content on Rock-Eval hydrogen index in oil shales and source rocks: Organic Geochemistry, v. 11, p. 351-369.Harvey, R. D., and Dillon, J. W., 1985, Maceral distributions in Illinois coals and their paleoenvironmental implications: International Journal of Coal Geology, v. 5, p. 141-165.Harvey, R.D., and C.W. Kruse, 1988, The Illinois Basin coal sample program: status and sample characterization: Journal of Coal Quality, v. 7, p. 109-113.Harvey, R.D., and I. Demir, 1992, Characterization of organic sulfur in macerals and chars: Illinois State Geological Survey Open File Series OFS 1992-1, 23 p.

Harvey, R.D., and J.W. Dillon, 1985, Maceral distributions in Illinois coals and their paleoenvironmental implications: International Journal of Coal Geology, v. 5, p. 141-165.Harvey, R.D., and P.J. DeMaris, 1987, Size and maceral association of pyrite in Illinois coals and their float-sink fractions: Organic Geochemistry, v. 11, p. 343-349.

Hassett, D.J., 1996, Ash research at the University of North Dakota Energy & Environmental Research Center: Energeia, v. 7, no. 4, p. 1, 3-5.Hassett, D.J., and K.E. Eylands, 1999, Mercury capture on coal combustion fly ash: Fuel, v. 78, p. 243-248.

Hatch, J.R., 1992, Hydrocarbon source-rock evaluation of Desmoinesian (Middle Pennsylvanian) coals from part of the Western Region of the Interior Coal Province, U.S.A. (abstract): AAPG 1992 Annual Convention Official Program, p. 53.Hatch, J.R., and M.J. Pawlewicz, 2007, Petroleum assessment of the Pottsville Coal Total Petroleum System, Black Warrior Basin, Alabama and Mississippi: U.S. Geological Survey Digital Data Series DDS-69-I, chapter 4, 33 p.Hatch, J.R., H.J. Gluskoter, and P.C. Lindahl, 1976, Sphalerite in coals from the Illinois Basin: Economic Geology, v. 71, p. 613-624.

Hatcher, P.G., 1990, Chemical structural models for coalified wood (vitrinite) in low rank coal: Organic Geochemistry, v. 16, p. 959-968.Hatcher, P.G., 1990, Chemical structural models for coalified wood (vitrinite) in low rank coal: Organic Geochemistry, v. 16, p. 959-968.Hatcher, P.G., and D.J. Clifford, 1997, The organic geochemistry of coal: from plant materials to coal: Organic Geochemistry, v. 27, p. 251-274.Hatcher, P.G., and D.J. Clifford, 1997, The organic geochemistry of coal: from plant materials to coal: Organic Geochemistry, v. 27, p. 251-274.Hatcher, P.G., and D.L. Clifford, 1997, The organic geochemistry of coal: from plant materials to coal: Organic Geochemistry, v. 27, p. 251-274.

Hatcher, P.G., H.E. Lerch, III, and T.V. Verheyen, 1989, Organic geochemical studies of the transformation of gymnospermous xylem during peatification and coalification to subbituminous coal: International Journal of Coal Geology, v. 13, p. 65-97.Hatcher, P.G., I.A. Breger, N. Szeverenyi, and G.E. Maciel, 1982, Nuclear magnetic resonance studies of ancient buried wood—II. Observations on the origin of coal from lignite to bituminous coal: Organic Geochemistry, v. 4, p. 9-18.Hatcher, P.G., J. Faulon, K.A. Wenzel, and G.D. Cody, 1992, A structural model for lignin-derived vitrinite from high-volatile bituminous coal (coalified wood): Energy and Fuels, v. 6, p. 813-820.Hatcher, P.G., M.A. Wilson, A.M. Vassallo, and H.E. Lerch, III, 1989, Studies of angiospermous wood in Australian brown coal by nuclear magnetic resonance and analytical pyrolysis: new insights into the early coalification process: International Journal of Coal Geology, v. 13, p. 99-126.

Hart, G.F., 1994, Maceral palynofacies of the Louisiana deltaic plain in terms of organic constituents and hydrocarbon potential, in A. Traverse, ed., Sedimentation of organic particles: Cambridge University Press, p. 141-176.Hart, G.F., M.A. Pasley, and W.A. Gregory, 1994, Particulate organic matter, maceral facies models, and applications to sequence stratigraphy, in A. Traverse, ed., Sedimentation of organic particles: Cambridge University Press, p. 337-390.

Hartkopf-Fröder, C., G.D. Wood, and K. Krainer, 2001, Palynology of the Permian Bolzano volcanic complex, southern Alps, Italy, part 1: miospore preservation, quantitative spore color and quantitative fluorescence microscopy, in Proceedings of the IX International Palynological Congress, Houston, Texas, U.S.A., 1996: American Association of Stratigraphic Palynologists, p. 79-97.

Harvey, R.D., and J.W. Dillon, 1985, Maceral distributions in Illinois coals and their paleoenvironmental implications, in T.L. Phillips and C.B. Cecil, eds., Paleoclimate controls on coal resources of the Pennsylvanian System of North America: International Journal of Coal Geology, v. 5, p. 141-165.

Harvey, R.D., and R.R. Ruch, 1986, Mineral matter in Illinois and other U.S. coals, in K.S. Vorres, ed., Mineral matter and ash in coal: Washington, D.C., American Chemical Society, ACS Symposium Series 301, p. 10-40.Haseldonckx, P., 1979, Relation of palynomorph colour and sedimentary organic matter to thermal maturation and hydrocarbon generating potential, in Generation and maturation of hydrocarbons in sedimentary basins: United Nations ESCAP, CCOP Technical Publication 6, p. 41-53.

Haszeldine, R.S., 1989, Coal reviewed: depositional controls, modern analogues and ancient climates, in M.K.G. Whateley and K.T. Pickering, eds., Deltas, sites and traps for fossil fuels: Boston, Blackwell Scientific Publications, Geological Society Special Publication 41, p. 289-308.

Hatcher, H.J., H.L.C. Meuzelaar, and D.T. Urban, 1992, A comparison of biomarkers in gilsonite, oil shale, tar sand and petroleum from Threemile Canyon and adjacent areas in the Uinta basin, Utah, in T.D. Fouch, V.F. Nuccio, and T.C. Chidsey, Jr., eds., Hydrocarbon and mineral resources of the Uinta basin, Utah and Colorado: Salt Lake City, Utah Geological Association, Guidebook 20, p. 271-287.

Hatcher, P.G., and H.E. Lerch, III, 1991, Survival of lignin-derived structural units in ancient coalified wood samples, in H.H. Schobert, K.D. Bartle, and L.J. Lynch, eds., Coal science II: Washington, D.C., American Chemical Society Symposium Series 461, p. 9-19.

Hathaway, D.L., 2006, Water and coal in the San Juan Basin: RMAG Outcrop, v. 55, no. 8, p. 1, 6-7.Hathaway, T. M., and R. A. Gayer, 1996, Thrust-related permeability in the South Wales coalfield: Geological Society of London Special Publication 109, p. 121-132.Hatt, R., 1988, Fuel quality for fluidized bed combustors: Journal of Coal Quality, v. 7, no. 4, p. 114-116.Hatt, R.M., and S.M. Rimmer, 1989, Classification and sampling of deposits from coal-fired boilers: Journal of Coal Quality, v. 8, no. 2, p. 40-44.Hatton, W., and A. Fardell, 2012, New discoveries of coal in Mozambique—Development of the coal resource estimation methodology for International Resource Reporting Standards: International Journal of Coal Geology, v. 89, p. 2-12.Havelcová, M., I. Sýkorová, A. Bechtel, K. Mach, H. Trejtnarová, M. Žaloudková, P. Matysová, J. Blažek, J. Boudová, and J. Sakala, 2013, "Stump horizon" in the Bílina mine (Most Basin, Czech Republic) — GC–MS, optical and electron microscopy in identification of wood biological origin: International Journal of Coal Geology, v. 107, p. 62-77.Havelcová, M., I. Sýkorová, H. Trejtnarová, and A. Šulc, 2012, Identification of organic matter in lignite samples from basins in the Czech Republic: Geochemical and petrographic properties in relation to lithotype: Fuel, v. 99, p. 129-142.Hawke, M.I., I.P. Martini, and L.D. Stasiuk, 1999, A comparison of temperate and boreal peats from Ontario, Canada: possible modern analogues from Permian coals: International Journal of Coal Geology, v. 41, p. 213-238.Hayatsu, R., R.L. McBeth, R.G. Scott, R.E. Botto, and R.E. Winans, 1984, Artificial coalification study: preparation and characterization of synthetic macerals: Organic Geochemistry, v. 6, p. 463-471.Hayes, J.B., 1991, Porosity evolution of sandstones related to vitrinite reflectance: Organic Geochemistry, v. 17, p. 117-129.Hays, D., J.W. Patrick, and A. Walker, 1976, Pore structure development during coal carbonization, 1. Behavior of single coals: Fuel, v. 55, p. 297-302.He, M., L. Ribeiro e Sousa, D. Elsworth, and E. Vargas, Jr., eds., 2012, CO2 storage in Carboniferous formations and abandoned coal mines: New York, CRC Press, 201 p.He, M.C., C.G. Wang, J.L. Feng, D.J. Li, and G.Y. Zhang, 2010, Experimental investigations on gas desorption and transport in stressed coal under isothermal conditions: International Journal of Coal Geology, v. 83, p. 377-386.He, S., M. Middleton, A. Kaiko, C. Jiang, and M. Li, 2002, Two case studies of thermal maturity and thermal modelling within the overpressured Jurassic rocks of the Barrow sub-basin, north west shelf of Australia: Marine and Petroleum Geology, v. 19, p. 143-159.He, S., M. Middleton, A. Kaiko, C. Jiang, and M. Li, 2002, Two case studies of thermal maturity and thermal modelling within the overpressured Jurassic rocks of the Barrow sub-basin, north west shelf of Australia: Marine and Petroleum Geology, v. 19, p. 143-159.Heath, J., and others, 2009, Seal analysis of geologic CO2 storage sites (abstract): AAPG Annual Convention and Exhibition, Abstracts Volume, p. 90-91.Heckel, P.H., 1977, Origin of phosphatic black shale facies in Pennsylvanian cyclothems of Mid-Continent North America: AAPG Bulletin, v. 61, p. 1045-1068.

Heckel, P.H., 1986, Sea-level curve for Pennsylvanian eustatic marine transgressive-regressive depositional cycles along Midcontinent outcrop belt, North America: Geology, v. 14, p. 330-334.

Hedberg, H.D., 1968, Significane of high-wax oils with respect to genesis of petroleum: AAPG Bulletin, v. 52, p. 736-750.Heidecke, H., and H.H. Oelert, 1991, Liquefaction potential of South African torbanite coal, 1) Basic tests for non-catalytic hydroliquefaction: Erdöl und Kohle-Erdgas-Petrochemie, v. 44, no. 4, p. 143-145.Heim, S., S.A. Jurisch, B.M. Krooss, P. Weniger, and R. Littke, 2012, Systematics of pyrolytic N2 and CH4 release from peat and coals of different thermal maturity: International Journal of Coal Geology, v. 89, p. 84-94.Heinemann, N., M. Wilkinson, R.S. Haszeldine, A.E. Fallick, and G.E. Pickup, 2013, CO2 sequestration in a UK North Sea analogue for geological carbon storage: Geology, v. 41, p. 411-414.Heller, R., and M. Zoback, 2014, Adsorption of methane and carbon dioxide on gas shale and pure mineral samples: Journal of Unconventional Oil and Gas Resources, v. 8, p. 14-24.Helms, J.R., X. Kong, E. Salmon, P.G. Hatcher, K. Schmidt-Rohr, and J. Mao, 2012, Structural characterization of gilsonite bitumen by advanced nuclear magnetic resonance spectroscopy and ultrahigh resolution mass spectrometry revealing pyrrolic and aromatic rings substituted with aliphatic chains: Organic Geochemistry, v. 44, p. 21-36.Hemborg, H.T., 1998, Spanish Peak field, Las Animas County, Colorado: geologic setting and early development of a coalbed methane reservoir in the central Raton basin: Colorado Geological Survey, Resource Series 33, 34 p.Hemish, L.A., 2002, Surface to subsurface correlation of methane-producing coal beds, northeast Oklahoma shelf: OGS Special Publication 2002-2, 22 p.Hemza, P., M. Sivek, and J. Jirásek, 2009, Factors influencing the methane content of coal beds of the Czech part of the Upper Silesian coal basin, Czech Republic: International Journal of Coal Geology, v. 79, p. 29-39.

Hendrix, M.S., S.C. Brassell, A.R. Carroll, and S.A. Graham, 1995, Sedimentology, organic geochemistry, and petroleum potential of Jurassic coal measures: Tarim, Junggar, and Turpan basins, northwest China: AAPG Bulletin, v. 79, p. 929-959.Heng, S., and M. Shibaoka, 1983, Hydrogenation of the inertinite macerals of Bayswater coal: Fuel, v. 62, p. 610-612.Henry, M.E., and T.M. Finn, 2003, Evaluation of undiscovered natural gas in the Upper Cretaceous Ferron coal/Wasatch Plateau total petroleum system, Wasatch Plateau and Castle Valley, Utah: International Journal of Coal Geology, v. 56, p. 3-37.Heppenheimer, H., K. Steffens, W. Püttmann, and W. Kalkreuth, 1992, Comparison of resinite-related aromatic biomarker distributions in Cretaceous-Tertiary coals from Canada and Germany: Organic Geochemistry, v. 18, p. 273-287.Herendeen, P.S., 1991, Charcoalified angiosperm wood from the Cretaceous of eastern North America and Europe: Review of Palaeobotany and Palynology, v. 70, p. 225-239.Heriawan, M.N., and K. Koike, 2008, Identifying spatial heterogeneity of coal resource quality in a multilayer coal deposit by multivariate geostatistics: International Journal of Coal Geology, v. 73, p. 307-330.Heriawan, M.N., and K. Koike, 2008, Uncertainty assessment of coal tonnage by spatial modeling of seam distribution and coal quality: International Journal of Coal Geology, v. 76, p. 217-226.

Heckel, P.H., 1985, Changing concepts of Midcontinent Pennsylvanian cyclothems, North America, in E.S. Belt and R.W. Macqueen, eds., Sedimentology and geochemistry, part 3: Neuvieme Congress International de Stratigraphie et de Geologie du Carbonifere, Southern Illinois University Press, Compte Rendu, v. 3, p. 535-553.Heckel, P.H., 1985, Current view of Midcontinent Pennsylvanian cyclothems, in W.L. Watney, R.L. Kaesler, and K.D. Newell, convenors, Recent interpretations of Late Paleozoic cyclothems: Midcontinent SEPM Proceedings of Third Annual Meeting and Field Conference, p. 1-22.

Heckel, P.H., 1988, Classic "Kansas" cyclothems, in O.T. Hayward, ed., South-Central Section of the Geological Society of America: Centennial Field Guide v. 4, Geological Society of America, p. 43-56.Heckel, P.H., 1994, Evaluation of evidence for glacio-eustatic control over marine Pennsylvanian cyclothems in North America and consideration of possible tectonic effects, in J.M. Dennison and F.R. Ettensohn, eds., Tectonic and eustatic controls on sedimentary cycles: SEPM Concepts in Sedimentology and Paleontology, v. 4, p. 65-87.Heckel, P.H., 2002, Genetic stratigraphy and conodont biostratigraphy of Upper Desmoinesian-Missourian (Pennsylvanian) cyclothem succession in Midcontinent North America, in L.V. Hills, C.M. Henderson, and E.W. Bamber, eds., Carboniferous and Permian of the World: Canadian Society of Petroleum Geologists Memoir 19, p. 99-119.Heckel, P.H., 2002, Overivew of Pennsylvanian cyclothems in Midcontinent North America and brief summary of those elsewhere in the World, in L.V. Hills, C.M. Henderson, and E.W. Bamber, eds., Carboniferous and Permian of the World: Canadian Society of Petroleum Geologists Memoir 19, p. 79-98.

Henderson, J.D., 1991, Evaluation of coalbed methane potential of Recluse Muddy field, Campbell County, Wyoming, in S.D. Schwochow, D.K. Murray, and M.F. Fahy, eds., Coalbed methane of western North America: Denver, CO, Rocky Mountain Association of Geologists Guidebook, p. 191-200.

Héroux, Y., A. Chagnon, and M. Savard, 1996, Organic matter and clay anomalies associated with base-metal sulfide deposits: Ore Geology Reviews, v. 11, p. 157-173.Héroux, Y., and R. Bertrand, 1991, Maturation thermique de la matiere organique dans un bassin du Paleozoique inferieur, basses-terres du Saint-Laurent, Quebec, Canada: Canadian Journal of Earth Sciences, v. 28, p. 1019-1030.Herrin, J.M., and D. Deming, 1996, Thermal conductivity of U.S. coals: Journal of Geophysical Research, v. 101, no. B11, p. 25,381-25,386.Hetényi, M., 1998, Oxygen index as an indicator of early organic maturity: Organic Geochemistry, v. 29, p. 63-77.

Hevia, V., and J.M. Virgos, 1977, The rank and anisotropy of anthracites: the indicating surface of reflectivity in uniaxial and biaxial substances: Journal of Microscopy, v. 109, pt. 1, p. 23-28.

Hickmott, D.D., and W.S. Baldridge, 1995, Application of PIXE microanalysis to macerals and sulfides from the Lower Kittaning coal of western Pennsylvania: Economic Geology, v. 90, p. 246-254.

Hildenbrand, A., B.M. Krooss, A. Busch, and R. Gaschnitz, 2006, Evolution of methane sorption capacity of coal seams as a function of burial history—a case study from the Campine Basin, NE Belgium: International Journal of Coal Geology, v. 66, p. 179-203.Hill, D.G., C.R. Nelson, and C.F. Brandenburg, 2000, Coalbed methane "frontier" expanding: American Oil & Gas Reporter, v. 43, no. 5, p. 83-85.Hill, P.A., 1988, The vertical distribution of minerals in coal zones A, B, C, D, Hat Creek, British Columbia: International Journal of Coal Geology, v. 10, p. 141-153.Hill, P.A., 1990, Vertical distribution of elements in Deposit no. 1, Hat Creek, British Columbia: a preliminary study: International Journal of Coal Geology, v. 15, p. 77-111.Hill, R., 2002, CBM: converting a resource into energy: World Coal, v. 11, p. 50-51, 53.Hill, R., 2002, CBM: converting a resource into energy: World Coal, v. 11, p. 50-51, 53.Hill, R., R. Rathbone, and J.C. Hower, 1998, Investigation of fly ash carbon by thermal analysis and optical microscopy: Cement and Concrete Research, v. 28, p. 1479-1488.Hillier, S.J., and J.E.A. Marshall, 1988, A rapid technique to make polished thin sections of sedimentary organic matter concentrates: Journal of Sedimentary Petrology, v. 58, p. 754-755.Hindmarsh, C.J., W. Wang, K.M. Thomas, and J.C. Crelling, 1994, The release of nitrogen during the combustion of macerals, microlithotypes, and their chars: Fuel, v. 73, p. 1229-1234.

Hodge, C.C., N.J. Russell, and M. Smyth, 1989, The significance of hydrocarbon shows and oil recoveries in the Longreach area, central Queensland: APEA Journal, v. 29, part 1, p. 157-174.Hodges, N.J., W.R. Ladner, and T.G. Martin, 1983, Chlorine in coal: a review of its origin and mode of occurrence: Journal Institute of Energy, v. 56, p. 158-169.Hoeft, A.P., D.E. Carlson, and M.R. Stevens, 1994, Effects of laboratory sample air dry depth and relative pulverizer temperature on apparent coal quality: Journal of Coal Quality, v. 13, p. 88-93.Hoffman, G.K., 2000, Use of fly ash from New Mexico coals (abstract): AAPG Bulletin, v. 84, p. 1240.Hoffman, G.K., and B.S. Brister, 2003, New Mexico’s Raton Basin coalbed methane play: New Mexico Geology, v. 25, no. 4, p. 95-110.Hoffman, G.L., G.R. Jordan, and G.R. Wallis, 1982, Geophysical borehole logging handbook for coal exploration: Edmonton, Alberta, Canada, The Coal Mining Research Centre, 270 p.Hoffmann, E., and A. Jenkner, 1932, Die inkohlung und ihre erkennung im mikrobild: Gluckauf, v. 68, p. 81-88.Hoffmann, E., and A. Jenkner, 1933, Fuel in science and practice: Fuel, v. 12, p. 100.

Hogan, W.T., 1971, Economic history of the iron and steel industry in the United States: Lexington, MA, D.C. Heath and Co., 217 p.Hohn, M.E., and J.Q. Britton, 2013, A geostatistical case study in West Virginia: All coals are not the same: International Journal of Coal Geology, v. 112, p. 125-133.Hol, S. C.J. Peach, and C.J. Spiers, 2011, Applied stress reduces the CO2 sorption capacity of coal: International Journal of Coal Geology, v. 85, p. 128-142.Hol, S. C.J. Peach, and C.J. Spiers, 2011, Applied stress reduces the CO2 sorption capacity of coal: International Journal of Coal Geology, v. 85, p. 128-142.Hol, S., C.J. Peach, and C.J. Spiers, 2012, Effect of 3-D stress state on adsorption of CO2 by coal: International Journal of Coal Geology, v. 93, p. 1-15.Hol, S., Y. Gensterblum, and C.J. Spiers, 2013, Direct determination of total CO2 uptake in coal: A new technique compared with the manometric method: Fuel, v. 105, p. 192-205.Hol, S., Y. Gensterblum, and P. Massarotto, 2014, Sorption and changes in bulk modulus of coal—experimental evidence and governing mechanisms for CBM and ECBM applications: International Journal of Coal Geology, v. 128-129, p. 119-133.Hol, S., Y. Gensterblum, and P. Massarotto, 2014, Sorption and changes in bulk modulus of coal—experimental evidence and governing mechanisms for CBM and ECBM applications: International Journal of Coal Geology, v. 128-129, p. 119-133.Holder, D., 2006, Eastern Kansas coals hold years of production: American Oil & Gas Reporter, v. 49, no. 11, p. 129-131.Holder, D., 2006, Illinois Basin’s mature areas yielding new potential: American Oil & Gas Reporter, v. 49, no. 6, p. 133-136.Holder, D., 2007, Admiral Bay finds the compression key that is unlocking eastern Kansas coals: American Oil & Gas Reporter, v. 50, no. 5, p. 104-114.

Hermanrud, C., G.M.G. Teige, M. Iding, O. Eiken, L. Rennan, and S. Østmo, 2010, Differences between flow of injected CO2 and hydrocarbon migration, in B.A. Vining and S.C. Pickering, eds., Petroleum geology: from mature basins to new frontiers: London, Geological Society, Proceedings of the 7 th Petroleum Geology Conference, p. 1183-1188.Herngreen, G.F.W., 1983, Palynological preparation techniques, in L.I. Costa, ed., Palynology-micropaleontology, laboratories, equipment and methods, v. 2: NPD Bulletin, p. 13-34.

Hetenyi, M., and C. Sajgo, 1990, Hydrocarbon generation potential of some Hungarian low-rank coals, in B. Durand and F. Behar, eds., Advances in organic geochemistry 1989, part II, molecular geochemistry: Organic Geochemistry, v. 16, p. 907-916.

Hewitt, J.L., 1984, Geologic overview, coal, and coalbed methane resources of the Warrior basin, Alabama and Mississippi, in C.T. Rightmire, G.E. Eddy, and J.N. Kirr, eds., Coalbed methane resources of the United States: AAPG Studies in Geology 17, p. 73-104.

Higgs, M.D., 1986, Laboratory studies into the generation of natural gas from coals, in J. Brooks, J.C. Goff, and B. van Hoorn, eds., Habitat of Paleozoic gas in N.W. Europe: Geological Society Special Publication 23, p. 113-120.

Hirschon, A.S., and R.B. Wilson, Jr., 1991, Dispersed catalysts for coal liquefaction, in H.H. Schobert, K.D. Bartle, and L.J. Lynch, eds., Coal science II: Washington, D.C., American Chemical Society, Symposium Series 461, p. 273-283.

Hofherr, K., 2000, State of the art in coke making and future development: 4 th European Coke and Ironmaking Congress, ATS, Paris, Proceedings, p. 686-692.

Holdgate, G.R., 2005, Geological processes that control lateral and vertical variability in coal seam moisture contents—Latrobe Valley (Gippsland Basin) Australia: International Journal of Coal Geology, v. 63, p. 130-155.

Holditch, S.A., R.H. Carter, and J.W. Ely, 1989, Coal seam stimulation manual: Gas Research Institute, Topical Report, GRI Contract No. 5087-214-1469.Hollub, V.A., and P.S. Schafer, 1992, A guide to coalbed methane operations: Gas Research Institute, 366 p.Hollub, V.A., and P.S. Schafer, 1992, A guide to coalbed methane operations: Gas Research Institute, 366 p. (chapter 3, wireline logging)Holman, R.W., 1990, Tandem mass spectrometric applications in fuel science: Journal of Coal Quality, v. 9, p. 120-124.Holtz, M.H., V. Núñez-López, and C. Breton, 2005, Moving Permian Basin technology to the Gulf Coast: The geologic distribution of CO2 EOR potential in Gulf Coast reservoirs: West Texas Geological Society Publication 05-115, 11 p.

Holz, M., W. Kalkreuth, and I. Banerjee, 2002, Sequence stratigraphy of paralic coal-bearing strata: an overview: International Journal of Coal Geology, v. 48, p. 147-179.Holz, M., W. Kalkreuth, and S.B.A. Rolim, 2010, Extension of the Paraná Basin to offshore Brazil: Implications for coalbed methane evaluation: Marine and Petroleum Geology, v. 27, p. 1119-1132.Hong, B.D., and E.R. Slatick, 1994, Carbon dioxide emission factors for coal: EIA, Quarterly Coal Report, DOE/EIA-0121(94/1Q), p. 1-8.Hook, R.W., 2002, John C. Ferm: contributions to coal geology: International Journal of Coal Geology, v. 49, p. 69-80.Hook, R.W., and J.C. Hower, 1988, Petrography and taphonomic significance of the vertebrate-bearing cannel coal of Linton, Ohio (Westphalian D, upper Carboniferous): Journal of Sedimentary Petrology, v. 58, p. 72-80.

Horne, J.C., 2003, The influence of depositional environments on coal stratigraphy: Rocky Mountain Association of Geologists, Field Seminar, CD-ROM, 213 p.Horne, J.C., J.C. Ferm, F.T. Caruccio, and B.P. Baganz, 1978, Depositional models in coal exploration and mine planning in Appalachian region: AAPG Bulletin, v. 62, p. 2379-2411.Horne, J.C., J.C. Ferm, F.T. Caruccio, and B.P. Baganz, 1978, Depositional models in coal exploration and mine planning in Appalachian region: AAPG Bulletin, v. 62, p. 2379-2411.Horsfield, B., 1989, Practical criteria for classifying kerogens: some observations from pyrolysis-gas chromatography: Geochimica et Cosmochimica Acta, v. 53, p. 891-901.Horsfield, B., 1990, Evaluating kerogen type according to source quality, compositional heterogeneity and thermallability: Review of Palaeobotany and Palynology, v. 65, p. 357-365.

Hoş-Çebi, F., and S. Korkmaz, 2013, Organic geochemistry and depositional environments of Eocene coals in northern Anatolia, Turkey: Fuel, v. 113, p. 481-496.Hoşgőrmez, H., M.N. Yalçin, B. Cramer, P. Gerling, E. Faber, R.G. Schaefer, and U. Mann, 2002, Isotopic and molecular composition of coal-bed gas in the Amasra region (Zonguldak basin—western Black Sea): Organic Geochemistry, v. 33, p. 1429-1439.Hoth, P., B. Mingram, V. Lüders, and E.P. Müller, 2002, New indications for the genesis and migration of nitrogen-rich gases in northern Germany—fluid inclusion and nitrogen geochemistry studies of Permo-Carboniferous rocks: Erdöl Erdgas Kohle, v. 118, p. 566-571. (English abstract)Hou, Q., Y. Ju, J. Aitchison, H. Zhang, and Y. Wu, 2012, Tectonic history and coalbed gas genesis: Journal of Geological Research, v. 2012, 1 p.Hou, X., D. Ren, H. Mao, J. Lei, K. Jin, P.K. Chu, F. Reich, and D.H. Wayne, 1995, Application of imaging TOF-SIMS to the study of some coal macerals: International Journal of Coal Geology, v. 27, p. 23-32.Hough, D.C., and A. Sanyal, 1987, The role of petrography in the classification and combustion of coal: Energy World, no. 146, p. 7-10.

Houseknecht, D.W., and C.M.B. Weesner, 1997, Rotational reflectance of dispersed vitrinite from the Arkoma basin: Organic Geochemistry, v. 26, p. 191-206.Houseknecht, D.W., D.F. Bensley, L.A. Hathon, and P.H. Kastens, 1993, Rotational reflectance properties of Arkoma basin dispersed vitrinite: insights for understanding reflectance populations in high thermal maturity regions: Organic Geochemistry, v. 20, p. 187-196.

Howard, J.R., 1983, Fluidized beds: combustion and applications: New York, Elsevier, 379 p.Howard-Smith, I., and G.J. Werner, 1976, Coal conversion technology: Park Ridge, N.J., Noyes Data Corporation, Chemical technology review no. 66, 133 p.Howell, D.J., and J.C. Ferm, 1980, Exploration model for Pennsylvanian upper delta plain coals, southwest West Virginia: AAPG Bulletin, v. 64, p. 938-941.Hower, J.C., 1988, Additivity of hardgrove grindability: a case study: Journal of Coal Quality, v. 7, p. 68-70.Hower, J.C., 1989, Petrology of liquefaction residues from the Breckinridge cannel, western Kentucky: Organic Geochemistry, v. 14, p. 299-305.Hower, J.C., 1990, Hardgrove grindability index and petrology used as an enhanced predictor of coal feed rate: Energeia, v. 1, no. 6, p. 1-2.Hower, J.C., 1998, Interrelationship of coal grinding properties and coal petrology: Minerals and Metallurgical Processing, v. 15, no. 3, p. 1-16.Hower, J.C., 1998, Interrelationship of coal grinding properties and coal petrology: Minerals and Metallurgical Processing, v. 15, p. 1-16.Hower, J.C., 2008, Maceral/microlithotype partitioning with particle size of pulverized coal: Examples from power plants burning central Appalachian and Illinois Basin coals: International Journal of Coal Geology, v. 73, p. 213-218.

Holditch, S.A., 1992, Completion methods in coal seam reservoirs, in Coalbed methane: Society of Petroleum Engineers, Reprint Series 35, p. 102-111.Holditch, S.A., J.W. Ely, M.E. Semmelbeck, R.H. Carter, J. Hinkel, and R.G. Jeffrey, Jr., 1992, Enhanced recovery of coalbed methane through hydraulic fracturing, in Coalbed methane: Society of Petroleum Engineers, Reprint Series 35, p. 147-155.

Holuszko, M.E., and A. de Klerk, 2014, Coal processing and use for power generation, in T.M. Letcher, ed., Future energy, second edition: New York, Elsevier, p. 53-73.Holz, M., and W. Kalkreuth, 2004, Sequence stratigraphy and coal petrology applied to the Early Permian coal-bearing Rio Bonito Formation, Paraná Basin, Brazil, in J.C. Pashin and R.A. Gastaldo, eds., Sequence stratigraphy, paleoclimate, and tectonics of coal-bearing strata: AAPG Studies in Geology 51, p. 147-167.

Hoover, D.S., and F.K. Schweighardt, 1989, Analytical techniques for monitoring coal sample storage, in R. Klein and R. Wellek, eds., Sample selection, aging, and reactivity of coal: New York, John Wiley & Sons, p. 443-461.

Horsfield, B., K.L. Yordy, and J.C. Crelling, 1988, Determining the petroleum-generating potential of coal using organic geochemistry and organic petrology, in L. Mattavelli and L. Novelli, eds., Advances in organic geochemistry 1987, part I, organic geochemistry in petroleum exploration: Organic Geochemistry, v. 13, p. 121-129.

Houseknecht, D.W., and C. Spotl, 1993, Empirical observations regarding methane deadlines in deep basins and thrust belts, in D.G. Howell, ed., The future of energy gases: U.S. Geological Survey Professional Paper 1570, p. 217-231.

Houseknecht, D.W., W.M. Burns, and K.J. Bird, 2012, Thermal maturation history of Arctic Alaska and the southern Canada basin, in N.B. Harris and K.E. Peters, eds., Analyzing the thermal history of sedimentary basins: Methods and case studies: SEPM Special Publication 103, p. 199-219.

Hower, J.C., 2008, Maceral/microlithotype partitioning with particle size of pulverized coal: examples from power plants burning central Appalachian and Illinois Basin coals: International Journal of Coal Geology, v. 73, p. 213-218.Hower, J.C., 2012, Teaching-aid: Petrographic examination of coal-combustion fly ash: International Journal of Coal Geology, v. 92, p. 90-97.Hower, J.C., A.M. Graese, and J.G. Klapheke, 1987, Influence of microlithotype composition on Hardgrove grindability for selected eastern Kentucky coals: International Journal of Coal Geology, v. 7, p. 227-244.Hower, J.C., A.S. Trimble, and C.F. Eble, 2001, Temporal and spatial variations in fly ash quality: Fuel Processing Technology, v. 73, p. 37-58.Hower, J.C., A.S. Trimble, C.F. Eble, C.A. Palmer, and A. Kolker, 1999, Characterization of fly ash from low-sulfur and high-sulfur coal sources: partitioning of carbon and trace elements with particle size: Energy Sources, v. 21, p. 511-525.Hower, J.C., and A. Davis, 1981, Application of vitrinite reflectance anisotropy in evaluation of coal metamorphism: GSA Bulletin, v. 92, p. 350-366.Hower, J.C., and A. Davis, 1981, Vitrinite reflectance anisotropy as a tectonic fabric element: Geology, v. 9, p. 165-168.Hower, J.C., and A. Davis, 1999, Reflectance of liptinites in anthracite: examples from the southern anthracite field, Pennsylvania: TSOP Newsletter, v. 16, no. 1, p. 15-17.Hower, J.C., and A.E. Bland, 1989, Geochemistry of the Pond Creek coal bed, eastern Kentucky coalfield: International Journal of Coal Geology, v. 11, p. 205-226.Hower, J.C., and C.F. Eble, 2004, Coal facies studies in the eastern United States: International Journal of Coal Geology, v. 58, p. 3-22.Hower, J.C., and G.D. Wild, 1988, Relationship between Hardgrove Grindability Index and petrographic composition for high-volatile bituminous coals from Kentucky: Journal of Coal Quality, v. 7, p. 122-126.Hower, J.C., and G.D. Wild, 1988, Relationship between Hardgrove Grindability Index and petrographic composition for high-volatile bituminous coals from Kentucky: Journal of Coal Quality, v. 7, p. 122-126.Hower, J.C., and G.D. Wild, 1991, Maceral partitioning for selected eastern Kentucky coals: Journal of Coal Quality, v. 10, p. 159-163.Hower, J.C., and G.D. Wild, 1994, Maceral/microlithotype analysis evaluation fo coal grinding: examples from central Appalachian high volatile bituminous coals: Journal of Coal Quality, v. 13, p. 35-40.Hower, J.C., and G.D. Wild, 1994, Maceral/microlithotype analysis evaluation of coal grinding: examples from central Appalachian high volatile bituminous coals: Journal of Coal Quality, v. 13, p. 35-40.Hower, J.C., and G.D. Wild, 1995, Maceral/microlithotype analysis evaluation of coal grinding: examples from central Appalachian high volatile bituminous coals: Journal of Coal Quality, v. 13, p. 35-40.Hower, J.C., and G.T. Lineberry, 1988, The interaction of coal lithotype and coal cutting on the breakage characteristics of selected Kentucky coals: Journal of Coal Quality, v. 7, p. 88-95.Hower, J.C., and J. Knowles, 2006, Research directions in coal combustion product science and engineering: Energeia, v. 17, no. 1, p. 5.Hower, J.C., and J.D. Robertson, 2003, Clausthalite in coal: International Journal of Coal Geology, v. 53, p. 219-225.Hower, J.C., and J.D. Robertson, 2004, Chemistry and petrology of fly ash derived from the co-combustion of western United States coal and tire-derived fuel: Fuel Processing Technology, v. 85, p. 359-377.Hower, J.C., and J.H. Calder, 1997, Maceral/microlithotype analysis of the Hardgrove grindability of lithotypes from the Phalen coal bed, Cape Breton, Nova Scotia: Minerals and Metallurgical Processing, v. 14, no. 1, p. 49-54.Hower, J.C., and K.W. Fishel, 1990, Anisotropy of coal reflectance: an example from the no. 5 seam ("Bollas") meta-anthracite, Peru: TSOP Newsletter, v. 7, no. 3, p. 10-11.Hower, J.C., and L.F. Ruppert, 2011, Splint coals for the central Appalachians: Petrographic and geochemical facies of the Peach Orchard No. 3 Split coal bed, southern Magoffin County, Kentucky: International Journal of Coal Geology, v. 85, p. 268-275.Hower, J.C., and M. Mastalerz, 2001, An approach toward a combined scheme for the petrographic classification of fly ash: Energy & Fuels, v. 15, p. 1319-1321.Hower, J.C., and M.L. Malinconico, 2000, Organic metamorphism in Middle Ordovician carbonates, Lebanon Valley nappe, Pennsylvania: International Journal of Coal Geology, v. 42, p. 221-230.Hower, J.C., and N.J. Wagner, 2012, Teaching aid: Notes on the methods of the combined maceral/microlithotype determination in coal: International Journal of Coal Geology, v. 95, p. 47-53.Hower, J.C., and T.L. Robl, 1993, Production of coal-combustion by-products in Kentucky: trends and prospects: Journal of Coal Quality, v. 12, p. 24-29.Hower, J.C., and W.G. Lloyd, 1999, Petrographic observations of Gieseler semi-cokes from high volatile bituminous coals: Fuel, v. 78, p. 445-451.Hower, J.C., C.F. Eble, and J.C. Quick, 2005, Mercury in eastern Kentucky coals: geologic aspects and possible reduction strategies: International Journal of Coal Geology, v. 62, p. 223-236. (see Quick, 2006, for equation correction)Hower, J.C., D.N. Taulbee, D.W. Kuhn, and C. Poole, 1986, Petrology and geochemistry of the Breckinridge seam: a torbanite from western Kentucky: Proceedings, 1986 Eastern Oil Shale Symposium, p. 267-280.Hower, J.C., D.N. Taulbee, S.M. Rimmer, and L.G. Morrell, 1994, Petrographic and geochemical anatomy of lithotypes from the Blue Gem coal bed, southeastern Kentucky: Energy and Fuels, v. 8, p. 719-728.Hower, J.C., D.N. Taulbee, S.M. Rimmer, and L.G. Morrell, 1994, Petrographic and geochemical anatomy of lithotypes from the Blue Gem coal bed, southeastern Kentucky: Energy and Fuels, v. 8, p. 719-728.

Hower, J.C., E.J. Trinkle, and G.D. Wild, 1984, Maceral and pyrite partitioning through high-gradient magnetic separation of selected western Kentucky coals: Fuel Processing Technology, v. 9, p. 203-213.Hower, J.C., E.J. Trinkle, and G.D. Wild, 1986, Maceral partitioning through beneficiation of Illinois Basin coals: Coal Preparation, v. 2, p. 149-164.Hower, J.C., E.J. Trinkle, and R.P. Raione, 2008, Vickers microhardness of telovitrinite and pseudovitrinite from high volatile bituminous Kentucky coals: International Journal of Coal Geology, v. 75, p. 76-80.Hower, J.C., G.A. Thomas, and J. Palmer, 1999, Impact of the conversion of low-Nox combustion on ash characteristics in a utility boiler burning western US coal: Fuel Processing Technology, v. 61, p. 175-195.Hower, J.C., G.A. Thomas, D.S. Clifford, J.D. Eady, J.D. Robertson, and A.S. Wong, 1996, Petrography and chemistry of high-carbon fly ash from the Shawnee Power Station, Kentucky: Energy Sources, v. 18, p. 107-118.Hower, J.C., G.A. Thomas, S.M. Mardon, and A.S. Trimble, 2005, Impact of co-combustion of petroleum coke and coal on fly ash quality: case study of a western Kentucky power plant: Applied Geochemistry, v. 20, p. 1309-1319.Hower, J.C., G.C. Copley, J.M.K. O’Keefe, and J.M. Hower, 2012, The further adventures of Tin Man: Vertical temperature gradients at the Lotts Creek coal mine fire, Perry County, Kentucky: International Journal of Coal Geology, v. 101, p. 16-20.Hower, J.C., G.D. Wild, and C.F. Eble, 1994, Coal quality considerations in the future production of metallurgical coal in eastern Kentucky: Journal of Coal Quality, v. 13, no. 1, p. 1-6.

Hower, J.C., D.N. Trerice, R.F. Rathbone, G.A. Thomas, and A.D. Hobbs, 1999, Short-term variations in fly ash petrology and mineralogy: examples from a western Pennsylvania power station: American Coal Ash Association, 13 th International Symposium on Use and Management of Coal Combustion Products, p. 28-1 to 28-10.

Hower, J.C., G.K. Hoffman, and T.M. Garrison, 2013, Macrinite and funginite forms in Cretaceous Menefee Formation anthracite, Cerrillos coalfield, New Mexico: International Journal of Coal Geology, v. 114, p. 54-59.Hower, J.C., H. Ban, J.L. Schaefer, and J.M. Stencel, 1997, Maceral/microlithotype partitioning through triboelectrostatic dry coal cleaning: International Journal of Coal Geology, v. 34, p. 277-285.Hower, J.C., H. Ban, J.L. Schaefer, and J.M. Stencel, 1997, Maceral/microlithotype partitioning through triboelectrostatic dry coal cleaning: International Journal of Coal Geology, v. 34, p. 277-286.Hower, J.C., I. Suárez-Ruiz, and M. Mastalerz, 2005, An approach toward a combined scheme for the petrographic classification of fly ash: revision and clarification: Energy and Fuels, v. 19, p. 653-655.

Hower, J.C., J.D. Robertson, A.S. Wong, C.F. Eble, and L.F. Ruppert, 1997, Arsenic and lead concentrations in the Pond Creek and Fire Clay coal beds, eastern Kentucky coal field: Applied Geochemistry, v. 12, p. 281-289.Hower, J.C., J.D. Robertson, and J.M. Roberts, 2001, Petrology and minor element chemistry of combustion by-products from the co-combustion of coal, tire-derived fuel, and petroleum coke at a western Kentucky cyclone-fired unit: Fuel Processing Technology, v. 74, p. 125-142.Hower, J.C., J.D. Robertson, G.A. Thomas, A.S. Wong, W.H. Schram, U.M. Graham, R.F. Rathbone, and T.L. Robl, 1996, Characterization of fly ash from Kentucky power plants: Fuel, v. 75, p. 403-411.Hower, J.C., J.D. Robertson, U.M. Graham, G.A. Thomas, A.S. Wong, and W.H. Schram, 1993, Characterization of Kentucky coal-combustion by-products: compositional variations based on sulfur content of feed coal: Journal of Coal Quality, v. 12, p. 150-155.

Hower, J.C., J.H. Calder, C.F. Eble, A.C. Scott, J.D. Robertson, and L.J. Blanchard, 2000, Metalliferous coals of the Westphalian A Joggins Formation, Cumberland Basin, Nova Scotia, Canada: petrology, geochemistry, and palynology: International Journal of Coal Geology, v. 42, p. 185-206.

Hower, J.C., J.L. Campbell, W.J. Teesdale, Z. Nejedly, and J.D. Robertson, 2008, Scanning proton microprobe analysis of mercury and other trace elements in Fe-sulfides from a Kentucky coal: International Journal of Coal Geology, v. 75, p. 88-92.Hower, J.C., J.M.K. O’Keefe, and C.F. Eble, 2008, Tales from a distant swamp: Petrological and paleobotanical clues for the origin of the sand coal lithotype (Mississippian, Valley Fields, Virginia): International Journal of Coal Geology, v. 75, p. 119-126.Hower, J.C., J.M.K. O’Keefe, C.F. Eble, A. Raymond, B. Valentim, T.J. Volk, A.R. Richardson, A.B. Satterwhite, R.S. Hatch, J.D. Stucker, and M.A. Watt, 2011, Notes on the origin of inertinite macerals in coal: Evidence for fungal and arthropod transformations of degraded macerals: International Journal of Coal Geology, v. 86, p. 231-240. [erratum, International Journal of Coal Geology, v. 116-117, p. 182.]Hower, J.C., J.M.K. O’Keefe, C.F. Eble, T.J. Volk, A.R. Richardson, A.B. Satterwhite, R.S. Hatch, and I.J. Kostova, 2011, Notes on the origin of inertinite macerals in coals: Funginite associations with cutinite and suberinite: International Journal of Coal Geology, v. 85, p. 186-190. [erratum, International Journal of Coal Geology, v. 116-117, p. 182.]Hower, J.C., J.M.K. O’Keefe, K.R. Henke, and A. Bagherieh, 2011, Time series analysis of CO concentrations from an eastern Kentucky coal fire: International Journal of Coal Geology, v. 88, p. 227-231.Hower, J.C., J.M.K. O’Keefe, K.R. Henke, N. J. Wagner, G. Copley, D.R. Blake, T. Garrison, M.L.S. Oliveira, R.M. Kautzmann, and L.F.O. Silva, 2013, Gaseous emissions and sublimates from the Truman Shepherd coal fire, Floyd County, Kentucky: A re-investigation following attempted mitigation of the fire: International Journal of Coal Geology, v. 116-117, p. 63-74.Hower, J.C., J.M.K. O’Keefe, M.A. Watt, T.J. Pratt, C.F. Eble, J.D. Stucker, A.R. Richardson, and I.J. Kostova, 2009, Notes on the origin of inertinite macerals in coals: Observations on the importance of fungi in the origin of macrinite: International Journal of Coal Geology, v. 80, p. 135-143.Hower, J.C., J.M.K. O’Keefe, N.J. Wagner, S. Dai, X. Wang, and W. Xue, 2013, An investigation of Wulantuga coal (Cretaceous, Inner Mongolia) macerals: Paleopathology of faunal and fungal invasions into wood and the recognizable clues for their activity: International Journal of Coal Geology, v. 114, p. 44-53.Hower, J.C., J.M.K. O’Keefe, T.J. Volk, and M.A. Watt, 2010, Funginite-resinite associations in coal: International Journal of Coal Geology, v. 83, p. 64-72.Hower, J.C., J.S. Esterle, G.D. Wild, and J.D. Pollock, 1990, Perspectives on coal lithotype analysis: Journal of Coal Quality, v. 9, p. 48-52.Hower, J.C., J.S. Esterle, G.D. Wild, and J.D. Pollock, 1990, Prespectives on coal lithotype analysis: Journal of Coal Quality, v. 9, no. 2, p. 48-52.Hower, J.C., J.T. Riley, G.A. Thomas, and T.B. Griswold, 1991, Chlorine in Kentucky coals: Journal of Coal Quality, v. 10, p. 152-158.Hower, J.C., K. Henke, J.M.K. O’Keefe, M.A. Engle, D.R. Blake, and G.B. Stracher, 2009, The Tiptop coal-mine fire, Kentucky: Preliminary investigation of the measurement of mercury and other hazardous gases from coal-fire gas vents: International Journal of Coal Geology, v. 80, p. 63-67.Hower, J.C., K.B. Anderson, G. Mackay, H. Pinheiro, D. Flores, and M.J. Lemos de Sousa, 1994, Interlaboratory comparisons of petrography of liquefaction residues from three Argonne premium coals: Organic Geochemistry, v. 22, p. 27-32.Hower, J.C., K.W. Kuehn, B.K. Parekh, and W.J. Peters, 2000, Maceral and microlithotype beneficiation in column flotation at the Powell Mountain Coal Mayflower preparation plant, Lee County, Virginia: Fuel Processing Technology, v. 67, p. 23-33.Hower, J.C., K.W. Kuehn, B.K. Parekh, and W.M. Andrews, Jr., 1997, Maceral and microlithotype response to oil agglomeration for selected eastern Kentucky high volatile A bituminous coals: Fuel Processing Technology, v. 50, p. 185-198.Hower, J.C., K.W. Kuehn, B.K. Parekh, and W.M. Andrews, Jr., 1997, Maceral and microlithotype response to oil agglomeration for selected eastern Kentucky high volatile A bituminous coals: Fuel Processing Technology, v. 50, p. 185-198.Hower, J.C., L.F. Ruppert, and C.F. Eble, 1999, Lanthanide, yttrium, and zirconium anomalies in the Fire Clay coal bed, eastern Kentucky: International Journal of Coal Geology, v. 39, p. 141-153.Hower, J.C., L.F. Ruppert, and D.A. Williams, 2002, Controls on boron and germanium distribution in the low-sulfur Amos coal bed, western Kentucky coalfield, USA: International Journal of Coal Geology, v. 53, p. 27-42.Hower, J.C., L.J. Blanchard, and J.D. Robertson, 1998, Magnitude of minor element reduction through beneficiation of central Appalachian coals: Coal Preparation, v. 19, p. 213-229.Hower, J.C., L.J. Blanchard, and J.D. Robertson, 1998, Magnitude of minor element reduction through beneficiation of central Appalachian coals: Coal Preparation, v. 19, p. 213-229.Hower, J.C., M. Mastalerz, A. Drobniak, J.C. Quick, C.F. Eble, and M.J. Zimmerer, 2005, Mercury content of the Springfield coal, Indiana and Kentucky: International Journal of Coal Geology, v. 63, p. 205-227. (see Quick, 2006, for equation correction)Hower, J.C., M. Misz-Keenan, J.M.K. O’Keefe, M. Mastalerz, C.F. Eble, T.M. Garrison, M.N. Johnston, and J.D. Stucker, 2013, Macrinite forms in Pennsylvanian coals: International Journal of Coal Geology, v. 116-117, p. 172-181.Hower, J.C., M.M. Maroto-Valer, D.N. Taulbee, and T. Sakulpitakphon, 2000, Mercury capture by distinct fly ash carbon forms: Energy & Fuels, v. 14, p. 224-226.Hower, J.C., N.J. Wagner, J.M.K. O’Keefe, J.W. Drew, J.D. Stucker, and A.R. Richardson, 2012, Maceral types in some Permian southern African coals: International Journal of Coal Geology, v. 100, p. 93-107. (Gondwana)Hower, J.C., R.A. Keogh, and B.H. Davis, 1992, Petrography of liquefaction residues: high-vitrinite, high-sulfur Davis (western Kentucky No. 6) coal: Energy & Fuels, v. 6, p. 609-613.Hower, J.C., R.A. Keogh, and D.N. Taulbee, 1991, Petrology of liquefaction residues: maceral concentrates from a Pond Creek durain, eastern Kentucky: Organic Geochemistry, v. 17, p. 431-438.Hower, J.C., R.A. Keogh, D.N. Taulbee, and R.F. Rathbone, 1993, Petrography of liquefaction residues: semifusinite concentrates from a Peach Orchard coal lithotype, Magoffin County, Kentucky: Organic Geochemistry, v. 20, p. 167-176.

Hower, J.C., G.D. Wild, and U.M. Graham, 1995, Petrographic characterization of high-carbon fly ash samples from Kentucky power stations, in S.S. Tyson, T.H. Blackstock, J. Hunger, and A. Marshall, eds., Proceedings: 11 th International Symposium on use and management of coal combustion by-products: American Coal Ash Association, p. 62-1 to 62-12.

Hower, J.C., J.D. Pollock, and T.B. Griswold, 1991, Structural controls on the petrology and geochemistry of the Pond Creek coal seam, Pike and Martin Counties, eastern Kentucky, in D.C. Peters, ed., Geology in coal resource utilization: Fairfax, VA, Techbooks, p. 413-425 (available from AAPG)

Hower, J.C., J.D. Robertson, U.M. Graham, G.A. Thomas, and A.S. Wong, 1993, Characterization of Kentucky coal combustion by-products: compositional variations based on sulfur content of feed coal, in S.-H. Chiang, ed., Coal — energy and the environment: Tenth Annual International Pittsburgh Coal Conference, Proceedings, p. 1022-1025.

Hower, J.C., J.K. Hiett, G.D. Wild, and C.F. Eble, 1994, Coal resources, production, and quality in the eastern Kentucky coal field: perspectives on the future of steam coal production, in Nonrenewable resources, v. 3: Oxford University Press, p. 216-236.

Hower, J.C., R.B. Finkelman, R.F. Rathbone, and J. Goodman, 2000, Intra- and inter-unit variation in fly ash petrography and mercury adsorption: examples from a western Kentucky power station: Energy & Fuels, v. 14, p. 212-216.

Hower, J.C., R.F. Rathbone, G.D. Wild, and A. Davis, 1994, Observations on the use of vitrinite maximum reflectance versus vitrinite random reflectance for high volatile bituminous coals: Journal of Coal Quality, v. 13, p. 71-76.Hower, J.C., R.F. Rathbone, J.D. Robertson, G. Peterson, and A.S. Trimble, 1999, Petrology, mineralogy, and chemistry of magnetically-separated sized fly ash: Fuel, v. 78, p. 197-203.Hower, J.C., R.F. Rathbone, T.L. Robl, G.A. Thomas, B.O. Haeberlin, and A.S. Trimble, 1997, Case study of the conversion of tangential- and wall-fired units to low-Nox combustion: impact on fly ash quality: Waste Management, v. 17, p. 219-229.

Hower, J.C., S.F. Greb, J.C. Cobb, and D.A. Williams, 2000, Discussion on origin of vanadium in coals: parts of the western Kentucky (USA) no. 9 coal rich in vanadium: London, Journal of the Geological Society, v. 157, p. 1257-1259.Hower, J.C., S.F. Greb, K.W. Kuehn, and C.F. Eble, 2009, Did the Middlesboro, Kentucky, bolide impact event influence coal rank?: International Journal of Coal Geology, v. 79, p. 92-96.Hower, J.C., T.L. Robl, and G.A. Thomas, 1999, Changes in the quality of coal combustion by-products produced by Kentucky power plants, 1978 to 1997: consequences of Clean Air Act directives: Fuel, v. 78, p. 701-712.Hower, J.C., T.L. Robl, and G.A. Thomas, 1999, Changes in the quality of coal delivered to Kentucky power plants, 1978 to 1997: responses to Clean Air Act directives: International Journal of Coal Geology, v. 41, p. 125-155.Hower, J.C., T.L. Robl, C. Anderson, G.A. Thomas, T. Sakulpitakphon, S.M. Mardon, and W.L. Clark, 2005, Characteristics of coal utilization products (CCBs) from Kentucky power plants, with emphasis on mercury content: Fuel, v. 84, p. 1338-1350.

Hower, J.C., U.M. Graham, A.S. Wong, J.D. Robertson, B.O. Haeberlin, G. A Thomas, and W.H. Schram, 1997, Influence of flue-gas desulfurization systems on coal combustion by-product quality at Kentucky power stations burning high-sulfur coal: Waste Management, v. 17, p. 523-533.Hower, J.C., U.M. Graham, R.F. Rathbone, and T.L. Robl, 1994, Retorting potential of lignite overburden from clay mining: Journal of Coal Quality, v. 13, p. 113-117.Hower, J.C., W.H. Schram, and G.A. Thomas, 2000, Forensic petrology and geochemistry: tracking the source of a coal slurry spill, Lee County, Virginia: International Journal of Coal Geology, v. 44, p. 101-108.Hower, J.C., W.H. Schram, and G.A. Thomas, 2000, Forensic petrology and geochemistry: tracking the source of a coal slurry spill, Lee County, Virginia: International Journal of Coal Geology, v. 44, p. 101-108.

Hu, G., C. Yu, Y. Ni, S. Huang, and X. Tian, 2013, Comparative study of stable carbon and hydrogen isotopes of alkane gases sourced from the Longtan and Xujiahe coal-bearing measures in the Sichuan Basin, China: International Journal of Coal Geology, v. 116-117, p. 293-301.Huang, D., D. Zhang, J. Li, and X. Huang, 1991, Hydrocarbon genesis of Jurassic coal measures in the Turpan Bsain, China: Organic Geochemistry, v. 17, p. 827-837.Huang, H., J. Yang, Y. Yang, and X. Du, 2004, Geochemistry of natural gases in deep strata of the Songliao Basin, NE China: International Journal of Coal Geology, v. 58, p. 231-244.Huang, W.-L., 1996, Experimental study of vitrinite maturation kinetics: effects of temperature, time, pressure, water, and Hydrogen Index: Organic Geochemistry, v. 24, p. 233-241.Huang, W.-L., 1996, Experimental study of vitrinite maturation: effects of temperature, time, pressure, water, and Hydrogen Index: Organic Geochemistry, v. 24, p. 233-241.

Hubbard, B., 1950, Coal as a possible petroleum source rock: AAPG Bulletin, v. 34, p. 2347-2351.

Huc, A.Y., P. Nederlof, R. Debarre, B. Carpentier, M. Boussafir, F. Laggoun-Defarge, A. Lenail-Chouteau, and N. Bordas-Le Floch, 2000, Pyrobitumen occurrence and formation in a Cambro-Ordovician sandstone reservoir, Fahud Salt Basin, North Oman: Chemical Geology, v. 168, p. 99-112.Hudspith, V., A.C. Scott, M.E. Collinson, N. Pronina, and T. Beeley, 2012, Evaluating the extent to which wildfire history can be interpreted from inertinite distribution in coal pillars: An example from the Late Permian, Kuznetsk Basin, Russia: International Journal of Coal Geology, v. 89, p. 13-25.Hudspith, V., A.C. Scott, M.E. Collinson, N. Pronina, and T. Beeley, 2012, Evaluating the extent to which wildfire history can be interpreted from inertinite distribution in coal pillars: An example from the Late Permian, Kuznetsk Basin, Russia: International Journal of Coal Geology, v. 89, p. 13-25.Hudspith, V.A., S.M. Rimmer, and C.M. Belcher, 2014, Latest Permian chars may derive from wildfires, not coal combustion: Geology, v. 42, p. 879-882.Huffman, G.P., F.E. Huggins, G.R. Dunmyre, A.J. Pignocco, and M.-C. Lin, 1985, Comparative sensitivity of various analytical techniques to the low-temperature oxidation of coal: Fuel, v. 64, p. 849-856.Huggins, F., and F. Goodarzi, 2009, Environmental assessment of elements and polyaromatic hydrocarbons emitted from a Canadian coal-fired power plant: International Journal of Coal Geology, v. 77, p. 282-288.Huggins, F.E., 2002, Overview of analytical methods for inorganic constituents in coal: International Journal of Coal Geology, v. 50, p. 169-214.

Huggins, F.E., and G.P. Huffman, 1995, Chlorine in coal: an XAFS spectroscopic investigation: Fuel, v. 74, p. 556-559.Huggins, F.E., and G.P. Huffman, 2004, How do lithophile elements occur in organic association in bituminous coals?: International Journal of Coal Geology, v. 58, p. 193-204.

Huggins, F.E., G.P. Huffman, D.A. Kosmack, and D.E. Lowenhaupt, 1980, Mossbauer detection of goethite in coal and its potential as an indicator of coal oxidation: International Journal of Coal Geology, v. 1, p. 75-81.Huggins, F.E., G.P. Huffman, G.R. Dunmyre, M.J. Nardozzi, and M.C. Lin, 1987, Low temperature oxidation of bituminous coals: its detection and effect on coal conversion: Fuel Processing Technology, v. 15, p. 233-244.Huggins, F.E., L.B.A. Seidu, N. Shah, G.P. Huffman, R.Q. Honaker, J.R. Kyger, B.L. Higgins, J.D. Robertson, S. Pal, and M.S. Seehra, 2009, Elemental modes of occurrence in an Illinois #6 coal and fractions prepared by physical separation techniques at a coal preparation plant: International Journal of Coal Geology, v. 78, p. 65-76.Huggins, F.E., L.B.A. Seidu, N. Shah, J. Backus, G.P. Huffman, and R.Q. Honaker, 2012, Mobility of elements in long-term leaching tests on Illinois #6 coal rejects: International Journal of Coal Geology, v. 94, p. 326-336.

Hower, J.C., R.F. Rathbone, and G.D. Wild, 1993, Reflections on the use of Rmax vs. Rmean for high volatile bituminous coals: TSOP Newsletter, v. 10, no. 2, p. 6.

Hower, J.C., R.F. Rathbone, U.M. Graham, J.G. Groppo, S.M. Brooks, T.L. Robl, and S.S. Medina, 1995, Approaches to the petrographic characterization of fly ash: 11 th International Coal Testing Conference, May 10-12, p. 49-54.

Hower, J.C., T.L. Robl, R.F. Rathbone, J.G. Groppo, U.M. Graham, and D.N. Taulbee, 1996, Case studies of the impact of conversion to low-NOx combustion on fly ash petrology and mineralogy: Proceedings of 7 th Australian Coal Science Conference, Gippsland, Victoria, Australia, p. 347-354.Hower, J.C., T.L. Robl, R.F. Rathbone, W.H. Schram, and G.A. Thomas, 1997, Characterization of pre- and post-Nox conversion fly ash from the Tennessee Valley Authority’s John Sevier fossil plant, in Proceedings, 12th International Symposium on Coal Combustion By-Product (CCB) Management and Use: Electric Power Research Institute, p. 39-1 to 39-13.

http://www.gsa.state.al.us/gsa/CO2PAGE/40927R03.pdf

Huang, Z., M.A. Urynowicz, and P.J.S. Colberg, 2013, Bioassay of chemically treated subbituminous coal derivatives using Pseudomons putida F1: International Journal of Coal Geology, v. 115, p. 97-105.

Huc, A.Y., B. Durand, J. Roucachet, M. Vandenbroucke, and J.L. Pittion, 1986, Comparison of three series of organic matter of continental origin, in D. Leythaeuser and J. Rullkotter, eds., Advances in organic geochemistry 1985, part I, petroleum geochemistry: Organic Geochemistry, v. 10, p. 65-72.

Huggins, F.E., and G.P. Huffman, 1989, Coal weathering and oxidation: the early stages, in C.R. Nelson, ed., Chemistry of coal weathering: New York, Elsevier Science Publishers, Coal Science and Technology, v. 14, p. 33-60.

Huggins, F.E., G.P. Huffman, and R.J. Lee, 1982, Scanning electron microscope-based automated image analysis (SEM-AIA) and Mossbauer spectroscopy: quantitative characterization of coal minerals, in E.L. Fuller, Jr., ed., Coal and coal products: analytical characterization techniques: Washington, D.C., American Chemical Society, ACS Symposium Series 205, p. 239-258.

Huijun, L., W. Tairang, M. Zongjin, and Z. Wencai, 2004, Pressure retardation of organic maturation in clastic reservoirs: a case study from the Banqiao Sag, eastern China: Marine and Petroleum Geology, v. 21, p. 1083-1093.

Humez, P., J. Lions, P. Négrel, and V. Lagneau, 2014, CO2 intrusion in freshwater aquifers: Review of geochemical tracers and monitoring tools, classical uses and innovative approaches: Applied Geochemistry, v. 46, p. 95-108.Humphrey, H.B., 1959, Historical summary of coal-mine explosions in the United States: U.S. Bureau of Mines Information Circular 7900, 275 p.Hunt, J.M., 1963, Composition and origin of the Uinta basin bitumens: Utah Geological and Mineralogical Survey, Bulletin 54, p. 249-273.Hunt, J.M., 1978, Characterization of bitumens and coals: AAPG Bulletin, v. 62, p. 301-303.Hunt, J.M., 1979, Petroleum geochemistry and geology: San Francisco, W.H. Freeman Co., 617 p.

Hunt, J.M., F. Stewart, and P.A. Dickey, 1954, Origin of hydrocarbons of Uinta basin, Utah: AAPG Bulletin, v. 38, p. 1671-1698.

Hunt, J.W., and M. Smyth, 1989, Origin of inertinite-rich coals of Australian cratonic basins: International Journal of Coal Geology, v. 11, p. 23-46.Hunt, J.W., and M. Smyth, 1989, Origin of inertinite-rich coals of Australian cratonic basins: International Journal of Coal Geology, v. 11, p. 23-46.Huntjens, F.J., and D.W. van Krevelen, 1954, Chemical structure and properties of coal; II. Reflectance: Fuel, v. 33, p. 88-103.Hutchison, L.L., 1911, Preliminary report on the rock asphalt, asphaltite, petroleum and natural gas in Oklahoma: Oklahoma Geological Survey, Bulletin 2, 256 p.

Hutton, A., B. Daulay, Herudiyanto, C. Nas, A. Pujobroto, and H. Sutarwan, 1994, Liptinite in Indonesian Tertiary coals: Energy & Fuels, v. 8, p. 1469-1477.Hutton, A., B. Daulay, Herudiyanto, C. Nas, A. Pujobroto, and H. Sutarwan, 1994, Liptinite in Indonesian Tertiary coals: Energy & Fuels, v. 8, p. 1469-1477.Hutton, A., S. Bharati, and T. Robl, 1994, Chemical and petrographic classification of kerogen/macerals: Energy & Fuels, v. 8, p. 1478-1488.Hutton, A.C., 1985, Determination of shale oil yields by petrographic analysis: Fuel, v. 64, p. 1058-1062.Hutton, A.C., 1985, Organic petrography of the Rundle-Stuart oil shale deposit, Queensland: Australian Coal Geology, v. 5, p. 25-51.Hutton, A.C., 1986, Classification of Australian oil shales: Energy Exploration & Exploitation, v. 4, p. 81-93.Hutton, A.C., 1986, Classification of Australian oil shales: Energy Exploration and Exploitation, v. 4, p. 81-93.

Hutton, A.C., 1986, Duaringa—a bipartite oil shale deposit: Australian Coal Geology, v. 6, p. 27-40.Hutton, A.C., 1987, Petrographic approach to beneficiation of Australian oil shales: Fuel, v. 66, p. 314-318.Hutton, A.C., 1987, Petrographic classification of oil shales: International Journal of Coal Geology, v. 8, p. 203-231.Hutton, A.C., 1987, Petrographic classification of oil shales: International Journal of Coal Geology, v. 8, p. 203-231.

Hutton, A.C., 1994, Organic petrography and oil shales: University of Kentucky, Center for Applied Energy Research, Energeia, v. 5, no. 5, p. 1-4.

Hulatt, E., 1990, Geophysical log interpretation and coal recognition in the subsurface, in S. Stuhec, compiler, Introduction to coal sampling techniques for the petroleum industry: Alberta Research Concil, Coal-bed methane Information Series 111, p. 51-112.

Hunt, J.M., 1991, Generation of gas and oil from coal and other terrestrial organic matter, in P.K. Mukhopadhyay, M.G. Fowler, and W.G. Dow, eds., Selected papers from the symposium on coal and terrestrial organic matter as a source rock for petroleum: Organic Geochemistry, v. 17, p. 673-680.Hunt, J.M., 1996, Petroleum geochemistry and geology, 2nd ed.: New York, W.H. Freeman and Company, 743 p.Hunt, J.M., 1996, Petroleum geochemistry and geology, 2nd ed.: New York, W.H. Freeman and Company, 743 p. (p. 511-514)Hunt, J.M., 1996, Petroleum geochemistry and geology, 2nd ed.: New York, W.H. Freeman and Company, 743 p. (Rock-Eval, p. 341)

Hunt, J.W., 1982, Relationship between microlithotype and maceral composition of coals and geological setting of coal measures in the Permian basins of eastern Australia, in C.W. Mallett, ed., Coal resources: origin, exploration and utilization in Australia, Proceedings: Geological Society of Australia Coal Group, Symposium, p. 484-502.Hunt, J.W., and D.K. Hobday, 1984, Petrographic composition and sulphur content of coals associated with alluvial fans in the Permian Sydney and Gunnedah Basins, eastern Australia, in R.A. Rahmani and R.M. Flores, eds., Sedimentology of coal and coal-bearing sequences: Oxford, Blackwell Scientific, International Association of Sedimentologists, Special Publication 7, p. 61-84.Hunt, J.W., and D.K. Hobday, 1984, Petrographic composition and sulphur content of coals associated with alluvial fans in the Permian Sydney and Gunnedah basins, eastern Australia, in R.A. Rahmani and R.M. Flores, eds., Sedimentology of coal and coal-bearing sequences: Boston, Blackwell Scientific Publications, International Association of Sedimentologists, Special Publication 7, p. 43-60.

Hutny, W.P., J.A. MacPhee, L. Giroux, and J.T. Price, 1995, Experimental study on the combustion behaviour of coal under simulated blast furnace conditions, in J.A. Pajares and J.M.D. Tascon, eds., Coal science: New York, Elsevier, Coal Science and Technology 24, v. 1, p. 543-546.Huttinger, K.J., 1988, Kinetics of coal gasification, in Y. Yurum, ed., New trends in coal science: Boston, Kluwer Academic Publishers, p. 433-452.Huttinger, K.J., 1988, Transport and other effects in coal gasification, in Y. Yurum, ed., New trends in coal science: Boston, Kluwer Academic Publishers, p. 453-480.Hutton, A., 1991, Fluorescence microscopy in oil shale and coal studies, in C.E. Barker and O.C. Kopp, eds., Luminescence microscopy and spectroscopy: qualitative and quantitative applications: SEPM Short Course 25, p. 107-115.

Hutton, A.C., 1986, Classification of oil shales - a petrographic approach, in J.H. Gary, ed., Nineteenth Oil Shale Symposium Proceedings: Golden, Colorado School of Mines Press, p. 27-37.Hutton, A.C., 1986, Classification of oil shales—a petrographic approach, in J.H. Gary, ed., Nineteenth Oil Shale Symposium Proceedings: Golden, Colorado School of Mines Press, p. 27-37.

Hutton, A.C., 1988, The lacustrine Condor oil shale sequence, in Lacustrine petroleum source rocks: Boston, Blackwell Scientific Publications, Geological Society Special Publication 40, p. 329-340.Hutton, A.C., 1991, Fluorescence microscopy in oil shale and coal studies, in C.E. Barker and O.C. Kopp, eds., Luminescence microscopy and spectroscopy: qualitative and quantitative applications: SEPM Short Course 25, p. 107-115.Hutton, A.C., 1991, Fluorescence microscopy in oil shale and coal studies, in C.E. Barker and O.C. Kopp, eds., Luminescence microscopy and spectroscopy: quantitative and qualitative aspects: SEPM Short Course 25, p. 107-115.

Hutton, A.C., 1995, Organic petrography of oil shales, in C. Snape, ed., Composition, geochemistry and conversion of oil shales: Boston, Kluwer Academic Publishers, NATO ASI Series C, Mathematical and Physical Sciences, v. 455, p. 17-33.

Hutton, A.C., A.J. Kantsler, A.C. Cook, and D.M. McKirdy, 1980, Organic matter in oil shales: APEA Journal, v. 20, part 1, p. 44-67.Hutton, A.C., A.J. Kantsler, A.C. Cook, and D.M. McKirdy, 1980, Organic matter in oil shales: The APEA Journal, v. 20, pt. 1, p. 44-67.Hutton, A.C., and A.C. Cook, 1980, Influence of alginite on the reflectance of vitrinite from Joadja, N.S.W., and some other coals and oil shales containing alginite: Fuel, v. 59, p. 711-714.Hutton, A.C., and A.C. Cook, 1980, Influence of alginite on the reflectance of vitrinite from Joadja, N.S.W., and some other coals and oil shales containing alginite: Fuel, v. 59, p. 711-714.Hutton, A.C., and D.A. Henstridge, 1985, Pyrolysis of Tertiary oil shale by a dolerite intrusion, Stuart deposit, Queensland, Australia: Fuel, v. 64, p. 546-552.Hutton, A.C., and J.C. Hower, 1999, Cannel coals: implications for classification and terminology: International Journal of Coal Geology, v. 41, p. 157-188.Hutton, A.C., J. Korth, P.T. Crisp, and J. Ellis, 1986, Low temperature pyrolysis of three Tertiary oil shales from Queensland, Australia; a comparative chemical and petrographic study: Journal of Analytical and Applied Pyrolysis, v. 9, p. 323-333.Hutton, A.C., U.M. Graham, J.C. Hower, R.F. Rathbone, and T.L. Robl, 1996, Petrography of pyrolysis and pyrolysis-steam retorted residues from the alpha torbanite and the alpha cannel coal: Organic Geochemistry, v. 24, p. 219-226.Huvaz, O., H. Sarikaya, and O.M. Nohut, 2005, Nature of a regional dogleg pattern in maturity profiles from Thrace Basin, northwestern Turkey: a newly discovered unconformity or a thermal anomaly?: AAPG Bulletin, v. 89, p. 1373-1396.Huvaz, O., R.O. Thomsen, and S. Noeth, 2005, A method for analyzing geothermal gradient histories using the statistical assessment of uncertainties in maturity models: Journal of Petroleum Geology, v. 28, p. 107-117.Huy, P.Q., K. Sasaki, Y. Sugai, and S. Ichikawa, 2010, Carbon dioxide gas permeability of coal core samples and estimation of fracture aperture width: International Journal of Coal Geology, v. 83, p. 1-10.Huy, P.Q., K. Sasaki, Y. Sugai, and S. Ichikawa, 2010, Carbon dioxide gas permeability of coal core samples and estimation of fracture aperture width: International Journal of Coal Geology, v. 83, p. 1-10.

Hwang, R.J., S.C. Teerman, and R.M. Carlson, 1998, Geochemical comparison of reservoir solid bitumens with diverse origins: Organic Geochemistry, v. 29, p. 505-517.Hwang, R.J., S.C. Teerman, and R.M. Carlson, 1998, Geochemical comparison of reservoir solid bitumens with diverse origins: Organic Geochemistry, v. 29, p. 505-517.Hycrude, 1986, Beneficiation-hydroretorting of U.S. oil shales: Chicago, IL, Hycrude Corporation, Annual status report, variously paginated, U.S.D.O.E. Grant No. DE-FG21-85LC111066.Hyman, L.A., M.L. Brugler, D.H. Daneshjou, and H.A. Ohen, 1992, Advances in laboratory measurement techniques of relative permeability and capillary pressure for coal seams: Quarterly Review of Methane from Coal Seams Technology, v. 9, no. 2, p. 9-16.I.C.C.P. (International Committee for Coal and Organic Petrology), 1971, Determination of rank by reflectance measurement of vitrinite: I.C.C.P. International handbook of coal petrography, supplement to second edition, 16 p.

Iannacchione, A.T., and D.G. Puglio, 1979, Geology of the Lower Kittanning coalbed and related mining and methane emission problems in Cambria County, Pa: U.S. Bureau of Mines, Report of Investigations 8354, 31 p.Iannacchione, A.T., and D.G. Puglio, 1979, Methane content and geology of the Hartshorne coalbed in Haskell and Le Flore Counties, Oklahoma: U.S. Bureau of Mines Report of Investigations 8407, 14 p.Iannacchione, A.T., C.A. Kertis, D.W. Houseknecht, and J.H. Perry, 1983, Problems facing coal mining and gas production in the Hartshorne coalbeds of the western Arkoma basin, Oklahoma: U.S. Bureau of Mines Report of Investigations 8795, 25 p.Ibarra, J.V., E. Munoz, and R. Moliner, 1996, FTIR study of the evolution of coal structure during the coalification process: Organic Geochemistry, v. 24, p. 725-735.Ibrahimov, R.A., and K.K. Bissada, 2010, Comparative analysis and geological significance of kerogen isolated using open-system (palynological) versus chemically and volumetrically conservative closed-system methods: Organic Geochemistry, v. 41, p. 800-811.ICCP 2004, Graphite, semi-graphite, natural coke, and natural char classification (see Kwiecińska and Petersen, 2004).ICCP, 1963, International handbook of coal petrography (second edition): International Committee for Coal and Organic Petrology, unpagenated.

ICCP, 1998, The new vitrinite classification (ICCP System 1994): Fuel, v. 77, p. 349-358.ICCP, 2001, The new inertinite classification (ICCP System 1994): Fuel, v. 80, p. 459-471.ICCP, 2005, Classification of huminite—ICCP System 1994 (see Sýkorová and others, 2005).ICF Resources, Inc., 1990, The United States coalbed methane resource: Quarterly Review of Methane from Coal Seams Technology, v. 7, no. 3, p. 10-28. (Arkoma basin, 4 tcf, p. 12)Ide, T.S., M. Crook, and F.M. Orr, Jr., 2011, Magnetometer measurements to characterize a subsurface coal fire: International Journal of Coal Geology, v. 87, p. 190-196.Iglesias, M.J., A. Jiménez, J.C. del Río, and I. Suárez-Ruiz, 2000, Molecular characterisation of vitrinite in relation to natural hydrogen enrichment and depositional environment: Organic Geochemistry, v. 31, p. 1285-1299.Iglesias, M.J., G. de la Puente, E. Fuente, and J.J. Pis, 1998, Compositional and structural changes during aerial oxidation of coal and their relationships with technological properties: Vibrational Spectroscopy, v. 17, p. 41-52.Iglesias, M.J., J.C. del Río, F. Laggoun-Defarge, M.J. Cuesta, and I. Suarez-Ruiz, 2002, Control of the chemical structure in perhydrous coals by FTIR and Py-GC/MS: Journal of Analytical and Applied Pyrolysis, v. 62, p. 1-34.Ignasiak, B., and N. Berkowitz, 1974, Studies on coal blends: preparation and mechanical strengths of some experimental cokes: CIM Bulletin, p. 72-76.

Hutton, A.C., 1995, Organic petrography of oil shales, in C. Snape, ed., Composition, geochemistry and conversion of oil shales: Boston, Kluwer Academic Publishers, NATO ASI Series C, Mathematical and Physical Sciences, v. 455, p. 17-33.Hutton, A.C., 1995, Organic petrography: principles and techniques, in C. Snape, ed., Composition, geochemistry and conversion of oil shales: Boston, Kluwer Academic Publishers, NATO ASI Series C, Mathematical and Physical Sciences, v. 455, p. 1-16.

Hvoslef, S., S.R. Larter, and D. Leythaeuser, 1988, Aspects of generation and migration of hydrocarbons from coal-bearing strata of the Hitra Formation, Haltenbanken area, Norway, in L. Mattavelli and L. Novelli, eds., Advances in organic geochemistry 1987: Organic Geochemistry, v. 13, p. 525-536.

Iannacchione, A.T., and D.G. Puglio, 1979, Geological association of coalbed gas and natural gas from the Hartshorne Formation in Haskell and Le Flore Counties, Oklahoma, in A.T. Cross, ed., Compte Rendu, v. 4, Economic geology: coal, oil, and gas: IXICC, Carbondale, Southern Illinois University Press, p. 739-752.

ICCP, 1971, International handbook of coal petrography (1st supplement to 2nd edition): International Committee for Coal and Organic Petrology, unpagenated.ICCP, 1975, International handbook of coal petrography (2nd supplement to 2nd edition): International Committee for Coal and Organic Petrology, unpagenated.ICCP, 1975, International handbook of coal petrography (2nd supplement to 2nd edition): International Committee for Coal and Organic Petrology, unpagenated.ICCP, 1993, International handbook of coal petrography (3rd supplement to 2nd edition): International Committee for Coal and Organic Petrology, unpagenated.

Inan, S., M.N. Yalcin, and U. Mann, 1998, Expulsion of oil from petroleum source rocks: inferences from pyrolysis of samples of unconventional grain size: Organic Geochemistry, v. 29, p. 45-61.

Ingram, G.R., and J.D. Rimstidt, 1984, Natural weathering of coal: Fuel, v. 63, p. 292-296.Inoue, J., and S. Yoshikawa, 2003, Identification of charcoal in Quaternary sediments and estimation of the charred temperature by reflectance measurements and H/C ratio analysis and observation through reflectance and scanning electron microscopy: Journal of Geosciences, v. 46, no. 8, p. 127-134.Inoue, T., N. Suzuki, H. Hasegawa, and H. Saito, 2012, Differential transportation and deposition of terrestrial biomarkers in middle Eocene fluvial to estuarine environments, Hokkaido, Japan: International Journal of Coal Geology, v. 96-97, p. 39-48.

International conference on trace elements in coal, 1989, Proceedings: Journal of Coal Quality, v. 8, p. 63-124.IOGCC, 2002, Collected studies: coal seam natural gas: Oklahoma City, Interstate Oil and Gas Compact Commission, 396 p.Iordanidis, A., J. Buckman, A.G. Triantafyllou, and A. Asvesta, 2008, Fly ash-airborne particles from Ptolemais-Kozani area, northern Greece, as determined by ESEM-EDX: International Journal of Coal Geology, v. 73, p. 63-73.Irani, M.C., E.D. Thimons, T.G. Bobick, M. Deul, and M.G. Zabetakis, 1972, Methane emission from U.S. coal mines, a survey: U.S. Bureau of Mines Information Circular 8558, 58 p.Irani, M.C., J.H. Jansky, P.W. Jeran, and G.L. Hassett, 1977, Methane emission from U.S. coal mines in 1975, a survey: a supplement to Information Circulars 8558 and 8659: U.S. Bureau of Mines Information Circular 8733, 55 p.Irani, M.C., P.W. Jeran, and M. Deul, 1974, Methane emission from U.S. coal mines in 1973, a survey. A supplement to IC 8558: U.S. Bureau of Mines Information Circular 8659, 47 p.Isaacs, J.J., and R. Liotta, 1987, Oxidative weathering of Powder River basin coal: Energy and Fuels, v. 1, p. 349-351.Isaksen, G.H., D.J. Curry, J.D. Yeakel, and A.I. Jenssen, 1998, Controls on the oil and gas potential of humic coals: Organic Geochemistry, v. 29, p. 23-44.Ishikawa, I., M. Kase, Y. Abe, K. Ono, M. Sugata, and T. Nishi, 1983, Influence of post reaction strength of coke on blast furnace operation: Iron and Steel Society and American Institute of Mining, Metallurgical, and Petroleum Engineers, Proceedings, v. 42, p. 357-368.

Islam, M.R., and D. Hayashi, 2008, Geology and coal bed methane resource potential of the Gondwana Barapukuria coal basin, Dinajpur, Bangladesh: International Journal of Coal Geology, v. 75, p. 127-143.Islam, M.R., and R. Shinjo, 2009, Numerical simulation of stress distributions and displacements around an entry roadway with igneous intrusion and potential sources of seam gas emission of the Barapukuria coal mine, NW Bangladesh: International Journal of Coal Geology, v. 78, p. 249-262.Ivanova, A., and L. Zaitseva, 2004, Studies of the coal facies in western Ukraine (the Lvov-Lolyn Basin): International Journal of Coal Geology, v. 58, p. 67-73.Izadi, G., S. Wang, D. Elsworth, J. Liu, Y. Wu, and D. Pone, 2011, Permeability evolution of fluid-infiltrated coal containing discrete fractures: International Journal of Coal Geology, v. 85, p. 202-211. (swelling-induced sorption of CO2)Izadi, G., S. Wang, D. Elsworth, J. Liu, Y. Wu, and D. Pone, 2011, Permeability evolution of fluid-infiltrated coal containing discrete fractures: International Journal of Coal Geology, v. 85, p. 202-211. (swelling-induced sorption of CO2)Izquierdo, M., A.M. Tye, and S.R. Chenery, 2013, Measuring reactive pools of Cd, Pb and Zn in coal fly ash from the UK using isotopic dilution assays: Applied Geochemistry, v. 33, p. 41-49.Izquierdo, M., and X. Querol, 2012, Leaching behavior of elements from coal combustion fly ash: An overview: International Journal of Coal Geology, v. 94, p. 54-66.Izquierdo, M., and X. Querol, 2012, Leaching behavior of elements from coal combustion fly ash: An overview: International Journal of Coal Geology, v. 94, p. 54-66.

Jackman, H.W., R.L. Eissler, and F.H. Reed, 1957, Weathering of Illinois coals during storage: Illinois State Geological Survey Circular 227, 22 p.

Jackson, K.S., D.M. McKirdy, and J.A. Deckelman, 1984, Hydrocarbon generation in the Amadeus basin, central Australia: APEA Journal, v. 24, part 1, p. 42-65.Jackson, R.E., and K.J. Reddy, 2007, Trace element chemistry of coal bed natural gas produced water in the Powder River Basin, Wyoming: Environmental Science & Technology, v. 41, p. 5953-5959.Jacob, H., 1967, Petrologie von asphaltiten und asphaltischen pyrobitumina: Erdol und Kohle, v. 20, p. 393-400.

Jacob, H., 1985, Disperse solid bitumens as an indicator for migration and maturity in prospecting for oil and gas: Erdol & Kohle Erdgas Petrochemie, v. 38, p. 365.Jacob, H., 1985, Disperse solid bitumens as an indicator for migration and maturity in prospecting for oil and gas: Erdöl und Kohle-Erdgas-Petrochemie, v. 38, no. 8, p. 365.Jacob, H., 1989, Classification, structure, genesis and practical importance of natural solid oil bitumen ("migrabitumen"): International Journal of Coal Geology, v. 11, p. 65-79.Jacob, H., 1989, Classification, structure, genesis and practical importance of natural solid oil bitumen ("migrabitumen"): International Journal of Coal Geology, v. 11, p. 65-79.

Ignasiak, B.S., 1974, Prediction of coke properties, in J.F. Fryer, J.D. Campbell, and J.G. Speight, eds., Symposium on coal evaluation: Alberta Research Council, Information Series 76, p. 70-80.

Indiana Geological Survey, 2011, Indiana coal: macerals: Indiana Geological Survey, web site, http://igs.indiana.edu/Coal/Macerals.cfm. Indiana Geological Survey, 2011, Indiana coal: macerals: Indiana Geological Survey, web site, http://igs.indiana.edu/Coal/Macerals.cfm.

International Committee for Coal Petrology (I.C.C.P.), 1963, 1971, International Handbook of Coal Petrography, 2 nd ed. (1963); suppl. To 2nd ed. (1971): Centre Nat. de Rech. Sci., Paris.

Isidro, A., A. Formoso, J.J. Pis, S. Ferreira, E. Fuente, J.M. Rivas, L. Garcia, and A. Cores, 1995, Combustion characteristics of different types of coal under blast furnace conditions, in J.A. Pajares and J.M.D. Tascon, eds., Coal science: New York, Elsevier, Coal Science and Technology 24, v. 1, p. 551-554.

Jackman, H.W., and R.J. Helfinstine, 1968, Drying and preheating coals before coking, Part 2, Coal blends: Illinois State Geological Survey, Circular 434, 23 p. http://library.isgs.uiuc.edu/Pubs/pdfs/circulars/c434.pdf Jackman, H.W., and R.J. Helfinstine, 1976, A survey of the coking properties of Illinois coals: Illinois State Geological Survey, Circular 412, 27 p. http://library.isgs.uiuc.edu/Pubs/pdfs/circulars/c412.pdf

Jackman, H.W., R.L. Eissler, and R.J. Helfinstine, 1959, Coke from medium-volatile and Illinois coals: Illinois State Geological Survey, Circular 278, 24 p. http://library.isgs.uiuc.edu/Pubs/pdfs/circulars/c278.pdf Jackson, D., 1985, American gilsonite: mining solid hydrocarbon, in M.D. Picard, ed., Geology and energy resources, Uinta basin of Utah: Salt Lake City, Utah Geological Association, Publication 12, p. 257-262.

Jacob, H., 1975, Mikroskopphotometrische analyse naturlicher fester erdolbitumina, in B. Alpern, ed., Petrographie de la matiere organique des sediments, relations avec la paleotemperature et le potentiel petrolier: Paris, Editions du Centre National de la Recherche Scientifique, p. 103-113.

Jacob, H., 1993, Nomenclature, classification, characterization, and genesis of natural solid bitumen (migrabitumen), in J. Parnell, H. Kucha, and P. Landais, eds., Bitumens in ore deposits: New York, Springer-Verlag, p. 11-27.Jacob, H., 1993, Nomenclature, classification, characterization, and genesis of natural solid bitumen (migrabitumen), in J. Parnell, H. Kucha, and P. Landais, eds., Bitumens in ore deposits: New York, Springer-Verlag, p. 11-27.

Jacob, H., and H. Wehner, 1981, Mikroskopphotometrische analyse disperser festbitumina in sedimenten: Deutsche Gesellschaft fur Mineralolwissenschaft und Kohlechemie, DGMK-Projekt 232, 257 p.Jacobsen, R.J., C.G. Treworgy, C. Chenoweth, and M.H. Bargh, 1996, Availability of coal resources in Illinois: Mt. Carmel Quadrangle, southeastern Illinois: Illinois State Geological Survey, Illinois Minerals 114, 39 p.

Jacobson, S.R., J.R. Hatch, S.C. Teerman, and R.A. Askin, 1988, Middle Ordovician organic matter assemblages and their effect on Ordovician-derived oils: AAPG Bulletin, v. 72, p. 1090-1100.Jaffe, L.A., B. Peucker-Ehrenbrink, and S.T. Petsch, 2002, Mobility of rhenium, platinum group elements and organic carbon during black shale weathering: Earth Planet. Sci. Letters, v. 198, p. 339-353.Jakab, E., B. Hoesterey, W. Windig, G.R. Hill, and H.L.C. Meuzelaar, 1988, Effects of low temperature air oxidation (weathering) reactions on the pyrolysis mass spectra of US coals: Fuel, v. 67, p. 73-79.

Jakeman, B.L., and A.C. Cook, 1978, The dispersion of some optical properties of vitrinite: Journal of Microscopy, v. 112, pt. 2, p. 183-195.Jamieson, E.D., 1993, Coal supply prospects in North America: London, IEA Coal Research, 93 p.Jangbarwala, J., 2008, Custom-designed process treats CBM produced water: Oil & Gas Journal, v. 106.25, p. 64-67.Jansen, G.J., 1987, Petrography studies can aid in coal mine planning and in estimating methane yields in coal beds: Mining Engineering, v. 39, no. 9, p. 849-852.Jansen, G.J., 1987, Petrography studies can aid in coal mine planning and in estimating methane yields in coal beds: Mining Engineering, v. 39, no. 9, p. 849-852.Jarmołowicz-Szulc, K., Ł. Karwowski, and L. Marynowski, 2012, Fluid circulation and formation of minerals and bitumens in the sedimentary rocks of the Outer Carpathians—Based on studies on the quartz–calcite–organic matter association: Marine and Petroleum Geology, v. 32, p. 138-158.Jarrett, P.M., ed., 1983, Testing of peats and organic soils: American Society for Testing and Materials (ASTM) Special Technical Publication STP 820, 241 p.Jarvie, D.M., 1991, Factors affecting Rock-Eval derived kinetic parameters: Chemical Geology, v. 93, p. 79-99.

Jasieńko, S., 1978, The nature of coking coals: Fuel, v. 57, p. 131-146.

Jasper, K., B.M. Krooss, G. Flajs, C. Hartkopf-Fröder, and R. Littke, 2009, Characteristics of type III kerogen in coal-bearing strata from the Pennsylvanian (Upper Carboniferous) in the Ruhr Basin, western Germany: Comparison of coals, dispersed organic matter, kerogen concentrates and coal-mineral mixtures: International Journal of Coal Geology, v. 80, p. 1-19.Jasper, K., B.M. Krooss, G. Flajs, C. Hartkopf-Fröder, and R. Littke, 2009, Characteristics of type III kerogen in coal-bearing strata from the Pennsylvanian (Upper Carboniferous) in the Ruhr Basin, western Germany: Comparison of coals, dispersed organic matter, kerogen concentrates and coal-mineral mixtures: International Journal of Coal Geology, v. 80, p. 1-19.Jasper, K., B.M. Krooss, G. Flajs, C. Hartkopf-Fröder, and R. Littke, 2009, Characteristics of type III kerogen in coal-bearing strata from the Pennsylvanian (Upper Carboniferous) in the Ruhr Basin, western Germany: Comparison of coals, dispersed organic matter, kerogen concentrates and coal-mineral mixtures: International Journal of Coal Geology, v. 80, p. 1-19.Jasper, K., C. Hartkopf-Fröder, G. Flajs, and R. Littke, 2010, Review article: evolution of Pennsylvanian (Late Carboniferous) peat swamps of the Ruhr Basin, Germany: comparison of palynological, coal petrographical and organic geochemical data: International Journal of Coal Geology, v. 83, p. 346-365.Jasper, K., C. Hartkopf-Fröder, G. Flajs, and R. Littke, 2010, Review paper: Palaeoecological evolution of Duckmantian wetlands in the Ruhr Basin (western Germany): A palynological and coal petrographical analysis: Review of Palaeobotany and Palynology, v. 162, p. 123-145.Jeffrey, E.C., 1910, The nature of some supposed algal coals: Proceedings of the American Academy of Arts and Sciences, v. 46, no. 12, p. 273-290.Jeffrey, E.C., 1915, The mode of origin of coal: Journal of Geology, v. 23, p. 218-230.Jelonek, I., K.J. Kruszewska, and P. Filipiak, 2007, Liptinite as an indicator of environmental changes during formation of coal seam No. 207 (Upper Silesia, Poland): International Journal of Coal Geology, v. 71, p. 471-487.Jelsema, C., and R. Paul, 2013, Spatial mixed effects model for compositional data with applications to coal geology: International Journal of Coal Geology, v. 114, p. 33-43.Jenden, P.D., and I.R. Kaplan, 1989, Origin of natural gas in Sacramento basin, California: AAPG Bulletin, v. 73, p. 431-453.

Jenkins, C.D., and C.M. Boyer, 2008, Coalbed and shale gas reservoirs: Journal of Petroleum Technology, v. 60, no. 2, p. 92-99.Jenkins, C.D., W.C. Riese, and R.A. Lamarre, 2002, The value of core description in characterizing coal bed methane reservoirs (abstract): AAPG Annual Convention Official Program, v. 11, p. A86.

Jeran, P.W., D.H. Lawhead, and M.C. Irani, 1976, Methane emissions from an advancing coal mine section in the Pittsburgh coalbed: U.S. Bureau of Mines Report of Investigations 8132, 10 p.Jerz, J.K., and J.D. Rimstidt, 2004, Pyrite oxidation in moist air: Geochimica et Cosmochimica Acta, v. 68, p. 701-714.Jia, J., A. Bechtel, Z. Liu, S.A.I. Strobl, P. Sun, and R.F. Sachsenhofer, 2013, Oil shale formation in the Upper Cretaceous Nenjiang Formation of the Songliao Basin (NE China): Implications from organic and inorganic geochemical analyses: International Journal of Coal Geology, v. 113, p. 11-26.Jiang, B., Z. Qu, G.G.X. Wang, and M. Li, 2010, Effects of structural deformation on formation of coalbed methane reservoirs in Huaibei coalfield, China: International Journal of Coal Geology, v. 82, p. 175-183.Jiang, Y., E.R. Elswick, and M. Mastalerz, 2008, Progression in sulfur isotopic compositions from coal to fly ash: Examples from single-source combustion in Indiana: International Journal of Coal Geology, v. 73, p. 273-284.Jimenez, A., F. Laggoun-Defarge, M.J. Iglesias, J.G. Prado, and I. Suarez-Ruiz, 1994, Significance of the resinization and oil impregnation processes in reflectance suppression of the vitrinite (abstract): ICCP News, no. 10, p. 10-11.

Jacobsen, S.R., 1991, Petroleum source rocks and organic facies, in R.K. Merrill, ed., Source and migration processes and evaluation techniques: AAPG Treatise of Petroleum Geology, Handbook of Petroleum Geology, p. 3-11. (mineral matrix effects on Rock-Eval, p. 9)Jacobson, R.J., 1983, Murphysboro Coal, Jackson, and Perry counties: Resources with low to medium sulfur potential: Illinois State Geological Survey, Illinois Minerals Notes 85, 19 p. http://library.isgs.uiuc.edu/Pubs/pdfs/illinoisminerals/im085.pdf Jacobson, S.R., 1991, Petroleum source rocks and organic facies, in R.K. Merrill, ed., Source and migration processes and evaluation techniques: AAPG Treatise Handbook 1, p. 3-11.

Jakab, E., Y. Yun, and H.L.C. Meuzelaar, 1989, Effects of weathering on the molecular structure of coal, in C.R. Nelson, ed., Chemistry of coal weathering: New York, Elsevier Science Publishers, Coal Science and Technology, v. 14, p. 61-82.

Jarvie, D.M., 1991, Total organic carbon (TOC) analysis, in R.K. Merrill, ed., Handbook of petroleum geology, source and migration processes and evaluation techniques: AAPG, Treatise of Petroleum Geology, p. 113-118.

Jasienko, S., H. Kidawa, and H. Machnikowska, 1981, Properties and structure of the petrographic components of bituminous coals and their behaviour during liquefaction, in Proceedings, International Conference on Coal Science: Essen, Verlag Glückauf GmbH, p. 28-33.

Jenisch, A., H.H. Richnow, and W. Michaelis, 1990, Chemical structural units of macromolecular coal components, in B. Durand and F. Behar, eds., Advances in organic geochemistry 1989, part II, molecular geochemistry: Organic Geochemistry, v. 16, p. 917-929.Jenkins, C., 2009, Estimating resources and reserves in coal-bed methane and shale gas reservoirs, in T. Carr, T. D’Agostino, W. Ambrose, J. Pashin, and N.C. Rosen, eds., Unconventional energy resources: making the unconventional conventional: 29 th Annual GCSSEPM Foundation Bob F. Perkins Research Conference, CD-ROM, p. 282-302.

Jenkins, R.G., and P.L. Walker, Jr., 1978, Analysis of mineral matter in coal, in C. Karr, Jr., ed., Analytical methods for coal and coal products, v. 2: New York, Academic Press, p. 265-292.

Jin, H., A. Schimmelmann, M. Mastalerz, J. Pope, and T.A. Moore, 2010, Coalbed gas desorption in canisters: Consumption of trapped atmospheric oxygen and implications for measured gas quality: International Journal of Coal Geology, v. 81, p. 64-72.Johnson, A.A., 2002, Zero emission coal—competitive, highly efficient electricity production from even high sulfur coals: Energeia, v. 13, no. 5, p. 1-3.

Johnson, E.A., 1990, Geology of the Fushun coalfield, Liaoning Province, People's Republic of China: International Journal of Coal Geology, v. 14, p. 217-236.

Johnson, R.C., and V.F. Nuccio, 1993, Surface vitrinite reflectance study of the Uinta and Piceance basins and adjacent areas, eastern Utah and western Colorado -- implications for the development of Laramide basins and uplifts: U.S. Geological Survey Bulletin 1787-DD, 38 p.Johnson, R.C., and V.F. Nuccio, 1993, Surface vitrinite reflectance study of the Uinta and Piceance basins and adjacent areas, eastern Utah and western Colorado - implications for the development of Laramide basins and uplifts: U.S. Geological Survey Bulletin 1787-DD, 38 p.

Johnson, R.C., T.J. Mercier, M.E. Brownfield, M.P. Bantea, and J.G. Self, 2009, Assessment of in-place oil shale resources of the Green River Formation, Piceance Basin, western Colorado: U.S. Geological Survey, Fact Sheet 2009-3012, 6 p.

Johnson, V.G., D.L. Graham, and S.P. Reidel, 1993, Methane in Columbia River basalt aquifers: isotopic and geohydrologic evidence for a deep coal-bed gas source in the Columbia basin, Washington: AAPG Bulletin, v. 77, p. 1192-1207.Johnston, D.J., 1990, Geochemical logs thoroughly evaluate coalbeds: Oil & Gas Journal, v. 88, no. 52, p. 45-51.Johnston, D.J., 1991, Interpreting wireline measurements in coal beds (abstract): AAPG Bulletin, v. 75, p. 1129-1130.

Johnston, J.H., R.J. Collier, and A.I. Maidment, 1991, Coal as source rocks for hydrocarbon generation in the Taranaki basin, New Zealand: a geochemical biomarker study: Journal of Southeast Asian Sciences, v. 5, p. 283-289.Johnston, M.N., J.C. Hower, and F.J. Rich, 2014, Notes on the origin of the resinite-rich "pine needle" lithotype of the Cretaceous Cambria coal, Weston County, Wyoming: International Journal of Coal Geology, v. 130, p. 66-69.

Jones, E.J.P., M.A. Voytek, M.D. Corum, and W.H. Orem, 2010, Stimulation of methane generation from a non-productive coal by addition of nutrients or a microbial consortia: Applied and Environmental Microbiology, v. 76, p. 7013-7022.Jones, E.J.P., M.A. Voytek, P.D. Warwick, M.D. Corum, A. Cohn, J.E. Bunnell, A.C. Clark, and W.H. Orem, 2008, Bioassay for estimating the biogenic methane-generating potential of coal samples: International Journal of Coal Geology, v. 76, p. 138-150.Jones, E.J.P., S.H. Harris, E.P. Barnhart, W.H. Orem, A.C. Clark, M.D. Corum, J.D. Kirshtein, M.S. Varonka, and M.A. Voytek, 2013, The effect of coal bed dewatering and partial oxidation on biogenic methane potential: International Journal of Coal Geology, v. 115, p. 54-63.Jones, J.C., 2010, The possible importance of solubility parameter in carbon dioxide sequestration in coal mines: Fuel, v. 89, p. 4061.Jones, J.M., A. Davis, A.C. Cook, D.G. Murchison, and E. Scott, 1984, Provincialism and correlations between some properties of vitrinites: International Journal of Coal Geology, v. 3, p. 315-331.Jones, J.M., and D.G. Murchison, 1963, The occurrence of resinite in bituminous coals: Economic Geology, v. 58, p. 263-273.Jones, J.M., and S. Creaney, 1977, Optical character of thermally metamorphosed coals of northern England: Journal of Microscopy, v. 109, pt. 1, p. 105-118.

Jones, J.M., D.G. Murchison, and S.A. Saleh, 1973, Reflectivity and anisotropy of vitrinites in some coal scares from the coal measures of northumberland: Proceedings of the Yorkshire Geological Society, v. 39, pt. 4, no. 24, p. 515-526.Jones, J.R., and B. Cameron, 1988, Modern coastal back-barrier environment: analog for coal basin or for carbonaceous black shale?: Geology, v. 16, p. 345-348. (comment in v. 17, p. 290)Jones, K.B., L.F. Ruppert, and S.M. Swanson, 2012, Leaching of elements from bottom ash, economizer fly ash, and fly ash from two coal-fired power plants: International Journal of Coal Geology, v. 94, p. 337-348.Jones, K.B., L.F. Ruppert, and S.M. Swanson, 2012, Leaching of elements from bottom ash, economizer fly ash, and fly ash from two coal-fired power plants: International Journal of Coal Geology, v. 94, p. 337-348.

Johnson, D.J., and P.L. Scholes, 1991, Predicting cleat in coal seams from mineral and maceral composition with wireline logs, in S.D. Schwochow, D.K. Murray, and M.F. fahy, Coalbed methane of western North America: Rocky Mountain Association of Geologists, p. 123-136.

Johnson, H., and A.G. Doré, 2010, Unconventional oil and gas resources and the geological storage of carbon dioxide: overview, in B.A. Vining and S.C. Pickering, eds., Petroleum geology: from mature basins to new frontiers: London, Geological Society, Proceedings of the 7 th Petroleum Geology Conference, p. 1061-1063.Johnson, H.R., P.M. Crawford, and J.W. Bunger, 2004, Strategic significance of America’s oil shale resource, v. 2, Oil shale resources, technology, and economics: U.S. Department of Energy Office of Naval Petroleum and Oil Shale Reserves, 57 p. http://www.fe.doe.gov/programs/reserves/publications/Pubs-NPR/npr_strategic_significancev2.pdfJohnson, H.R., P.M. Crawford, and J.W. Bunger, 2004, Strategic significance of America’s oil shale resource, v.1, Assessment of strategic issues: U.S. Department of Energy Office of Naval Petroleum and Oil Shale Reserves, 45 p. http://www.fe.doe.gov/programs/reserves/publications/Pubs-NPR/npr_strategic_significancev1.pdfJohnson, R.C., A.C. Clark, C.E. Barker, B.L. Crysdale, D.K. Higley, Jr., R.J. Szmajter, and T.M. Finn, 1993, Coalbed methane potential of the Upper Cretaceous Mesaverde and Meeteetse formations, Wind River Reservation, Wyoming, in W.R. Keefer and others, eds., Wyoming Geological Association special symposium on oil and gas and other resources of the Wind River basin, Wyoming: Casper, Wyoming Geological Association, p. 215-242.Johnson, R.C., and D.D. Rice, 1993, Variations in composition and origins of gases from coal bed and conventional reservoirs, Wind River basin, Wyoming, in W.R. Keefer and others, eds., Wyoming Geological Association special symposium on oil and gas and other resources of the Wind River basin, Wyoming: Casper, Wyoming Geological Association, p. 319-335.Johnson, R.C., and R.M. Flores, 1993, Stratigraphy, areal distribution, and paleodepositional environments of Fort Union Formation coal beds, Wind River Reservation, Wyoming; implications for coalbed methane development, in W.R. Keefer and others, eds., Wyoming Geological Association special symposium on oil and gas and other resources of the Wind River basin, Wyoming: Casper, Wyoming Geological Association, p. 281-294.Johnson, R.C., and R.M. Flores, 1998, Developmental geology of coalbed methane from shallow to deep in Rocky Mountain basins and in Cook Inlet — Matanuska basin, Alaska, U.S.A. and Canada, in R.M. Flores, ed., Coalbed methane: from coal-mine outbursts to a gas resource: International Journal of Coal Geology, v. 35, p. 241-282.

Johnson, R.C., C.E. Barker, M.J. Pawlewicz, B.L. Crysdale, A.C. Clark, and D.D. Rice, 1991, Preliminary results of a coalbed methane assessment of the Wind River Indian Reservation, Wyoming, in S.D. Schwochow, D.K. Murray, and M.F. Fahy, eds., Coalbed methane of western North America: Denver, CO, Rocky Mountain Association of Geologists Guidebook, p. 273-284.Johnson, R.C., Mercier, T.J., Brownfield, M.E., and Self, J.G., 2010, Assessment of in-place oil shale resources of the Green River Formation, Uinta Basin, Utah and Colorado: U.S. Geological Survey Fact Sheet 2010-3010, 4 p. http://pubs.usgs.gov/fs/2010/3010/Johnson, R.C., T.J. Mercier, M.E. Brownfield, and J.G. Self, 2010, Assessment of in-place oil shale resources in the Eocene Green River Formation, Uinta Basin, Utah and Colorado: U.S. Geological Survey, Digital Data Series DDS-69-BB, chapter 1, 162 p. http://pubs.usgs.gov/dds/dds-069/dds-069-bb/REPORTS/69_BB_CH_1.pdf

Johnson, R.C., T.J. Mercier, M.E. Brownfield, M.P. Pantea, and J.G. Self, 2010, An assessment of in-place oil shale resources in the Green River Formation, Piceance Basin, Colorado: U.S. Geological Survey, Digital Data Series DDS-69-Y, chapter 1, 197 p. http://pubs.usgs.gov/dds/dds-069/dds-069-y/REPORTS/69_Y_CH_1.pdfJohnson, R.C., T.J. Mercier, R.T. Ryder, M.E. Brownfield, and J.G. Self, 2011, Assessment of in-place oil shale resources of the Eocene Green River Formation, Greater Green River Basin, Wyoming, Colorado, and Utah: U.S. Geological Survey, Digital Data Series DDS-69-DD, chapter 1, 68 p. http://pubs.usgs.gov/dds/dds-069/dds-069-dd/REPORTS/69_DD_CH_1.pdfJohnson, T.A., 2004, Isopach mapping of Desmoinesian coals—Bourbon Arch region, eastern Kansas: Kansas Geological Survey, Open-File Report 2004-39. (http://www.kgs.ku.edu/PRS/publication/2004/OFR04_39/index.html)Johnson, T.A., 2004, Stratigraphy, depositional environment, and coalbed gas potential of Middle Pennsylvanian (Desmoinesian Stage) coal—Bourbon Arch region, eastern Kansas: Kansas Geological Survey, Open-File Report 2004-38. (http://www.kgs.ku.edu/PRS/publication/2004/OFR04_38/index.html)

Johnston, D.J., and P.L. Scholes, 1991, Predicting cleats in coal seams from mineral and maceral composition with wireline logs, in S.D. Schwochow, D.K. Murray, and M.F. Fahy, eds., Coalbed methane of western North America: Denver, CO, Rocky Mountain Association of Geologists Guidebook, p. 123-136.

Jones, A.H., G.J. Bell, and R.A. Schraufnagel, 1988, A review of the physical and mechanical properties of coal with implications for coal-bed methane well completion and production, in J.E. Fassett, ed., Geology and coal-bed methane resources of the northern San Juan basin, Colorado and New Mexico: Denver, Rocky Mountain Association of Geologists Guidebook, p. 169-181.

Jones, J.M., D.G. Murchison, and S.A. Saleh, 1972, Variation of vitrinite reflectivity in relation to lithology, in Advances in organic geochemistry 1971: Oxford, Pergamon Press, p. 601-612.Jones, J.M., D.G. Murchison, and S.A. Saleh, 1972, Variation of vitrinite reflectivity in relation to lithology, in Advances in organic geochemistry 1971: Oxford, Pergamon Press, p. 601-612.

Jones, N.R., R.M. Lyman, and R.H. De Bruin, 2004, Coalbed methane update: Wyoming Geo-notes, no. 79, p. 16-18.Jones, N.R., R.M. Lyman, and R.H. De Bruin, 2004, Coalbed methane update: Wyoming Geo-notes, no. 81, p. 21-24.

Jones, R.B., C.B. McCourt, C. Morley, and K. King, 1985, Maceral and rank influences on the morphology of coal char: Fuel, v. 64, p. 1460-1467.Jones, R.W., 1979, Some mass balance and geological constraints on migration mechanisms: Proceedings of the Indonesian Petroleum Association, Eighth Annual Convention, p. 143-157.

Jones, R.W., 1995, Micropalaeontology in petroleum exploration: New York, Oxford University Press, 416 p.Jones, R.W., and R.H. DeBruin, 1990, Coalbed methane in Wyoming: Geological Survey of Wyoming Public Information Circular 30, 15 p.

Jones, T., 1995, Controlling sulfur emissions from coal combustion: Energeia, v. 6, no. 2, p. 1-2.Jones, T.P., 1993, New morphological and chemical evidence for a wildfire origin for fusain from comparisons with modern charcoal: London, The Palaeontological Association, Special Papers in Palaeontology, No. 49, p. 113-123.

Jones, T.P., 1996, Comment on ‘Fossil charcoal in Cretaceous-Tertiary boundary strata: evidence for catastrophic firestorm and megawave’ by M.A. Kruge, B.A. Stankiewicz, J.C. Crelling, A. Montanari, and D.F. Bensley: Geochimica et Cosmochimica Acta, v. 60, p. 719-720.Jones, T.P., A.C. Scott, and D.P. Mattey, 1993, Investigations of "fusain transition fossils" from the lower Carboniferous: comparisons with modern partially charred wood: International Journal of Coal Geology, v. 22, p. 37-59.Jones, T.P., A.C. Scott, and M.J. Cope, 1991, Reflectance measurements and the temperature of formation of modern charcoals and implications for studies of fusain: Bull. Soc. Geol. France, v. 162, p. 193-200.Jones, T.P., and N.P. Rowe, eds., 1999, Fossil plants and spores: modern techniques: London, Geological Society, 396 p.Jones, T.P., and W.G. Chaloner, 1991, Fossil charcoal, its recognition and palaeoatmospheric significance: Palaeogeography, Palaeoclimatology, Palaeoecology, v. 97, p. 39-50.

Jongmans, W.J., R.G. Koopmans, and G. Roos, 1936, Nomenclature of coal petrography: Fuel, v. 15, p. 14-15.Jongwa, L.T., and A.M. Crouch, 2012, Mercury speciation in South African coal: Fuel, v. 94, p. 234-239.

Jordan, P.D., C.M. Oldenburg, and J.-P. Nicot, 2013, Measuring and modeling fault density for CO2 storage plume-fault encounter probability estimation: AAPG Bulletin, v. 97, p. 597-618.Jorjani, E., J.C. Hower, S.C. Chelgani, M.A. Shirazi, and S. Mesroghli, 2008, Studies of relationship between petrography and elemental analysis with grindability for Kentucky coals: Fuel, v. 87, p. 707-713.Jorjani, E., J.C. Hower, S.C. Chelgani, M.A. Shirazi, and S. Mesroghli, 2008, Studies of relationship between petrography and elemental analysis with grindability for Kentucky coals: Fuel, v. 87, p. 707-713.Jorjani, E., S. Esmaeili, and M. Tayebi Khorami, 2013, The effect of particle size on coal maceral group’s separation using flotation: Fuel, v. 114, p. 10-15.Joseph, J.T., 1991, Liquefaction behavior of solvent-swollen coals: Fuel, v. 70, p. 139-144.Joseph, J.T., R.B. Fisher, C.A. Masin, G.R. Dyrkacz, C.A. Bloomquist, and R.E. Winans, 1991, Coal maceral chemistry. 1. Liquefaction behavior: Energy & Fuels, v. 5, p. 724-729.Joubert, J.I., C.T. Grein, and D. Bienstock, 1973, Sorption of methane in moist coal: Fuel, v. 52, p. 181-185.Joubert, J.I., C.T. Grein, and D. Bienstock, 1974, Effect of moisture on the methane capacity of American coals: Fuel, v. 53, p. 186-191.Juckes, L.M., and G.J. Pitt, 1977, The standardization of petrographic analysis of coal: Journal of Microscopy, v. 109, pt. 1, p. 13-21.Jung, H.B., S. Kabilan, J.P. Carson, A.P. Kuprat, W. Um, P. Martin, M. Dahl, Y. Kafentzis, T. Varga, S. Stephens, B. Arey, K.C. Carroll, A. Bonneville, and C.A. Fernandez, 2014, Wellbore cement fracture evolution at the cement-basalt caprock interface during geologic carbon sequestration: Applied Geochemistry, v. 47, p. 1-16.Juntgen, H., 1987, Coal characterization in relation to coal combustion, part 1: structural aspects and combustion: Erdol und Kohle-Erdgas-Petrochemie, v. 40, p. 153-165.Juntgen, H., 1987, Coal characterization in relation to coal combustion, part 2: environmental problems of combustion: Erdol und Kohle-Erdgas-Petrochemie, v. 40, p. 204-208.

Jurisch, S.A., S. Heim, B.M. Krooss, and R. Littke, 2012, Systematics of pyrolytic gas (N2, CH4) liberation from sedimentary rocks: Contribution of organic and inorganic rock constituents: International Journal of Coal Geology, v. 89, p. 95-107.Jusino, A., and H.H. Schobert, 2006, The use of sulfur to extract hydrogen from coal: International Journal of Coal Geology, v. 65, p. 223-234.Kaegi, D.D., 1981, Predicting coke stability from coal petrographic analyses: Iron and Steel Society of AIME, Ironmaking Proceedings, v. 40, p. 381-392.Kaegi, D.D., 1985, On the identification and origin of pseudovitrinite: International Journal of Coal Geology, v. 4, p. 309-319.Kaegi, D.D., 1985, On the identification and origin of pseudovitrinite: International Journal of Coal Geology, v. 4, p. 309-319.

Jones, R.B, C. Morley, and C.B. McCourt, 1985, Maceral effects on the morphology and combustion of coal char, in Proceedings 1985 International Conference on Coal Science: Sydney, October 28-31, p. 669-672.

Jones, R.W., 1984, Comparison of carbonate and shale source rocks, in J. Palacas, ed., Petroleum geochemistry and source rock potential of carbonate rocks: AAPG Studies in Geology 18, p. 163-180.Jones, R.W., 1987, Organic facies, in J. Brooks and D. Welte, eds., Advances in petroleum geochemistry: London, Academic Press, v. 2, p. 1-90.

Jones, R.W., and T.A. Edison, 1978, Microscopic observations of kerogen related to geochemical parameters with emphasis on thermal maturation, in D.F. Oltz, ed., Low temperature metamorphism of kerogen and clay minerals: Los Angeles, S.E.P.M. Pacific Section, p. 1-12.Jones, R.W., and T.A. Edison, 1978, Microscopic observations of kerogen related to geochemical parameters with emphasis on thermal maturation, in D.F. Oltz, ed., Low temperature metamorphism of kerogen and clay minerals: Symposium in Geochemistry, The Pacific Section, SEPM, p. 1-12.

Jones, T.P., 1994, 13C enriched lower Carboniferous fossil plants from Donegal, Ireland: carbon isotope constraints on taphonomy, diagenesis and palaeoenvironment: Review of Palaeobotany and Palynology, v. 81, p. 53-64.

Jones, T.P., W.G. Chaloner, and T.A.J. Kuhlbusch, 1997, Proposed bio-geological and chemical based terminology for fire-altered plant matter, in J.S. Clark, H. Cachier, J.G. Goldammer, and B. Stocks, eds., Sediment records of biomass burning and global change: NATO ASI Series v. 51, p. 9-22.

Jordan, G., 1990, Desorption, diffusion and coal testing for coalbed methane, in S. Stuhec, compiler, Introduction to coal sampling techniques for the petroleum industry: Alberta Research Council, Coal-bed Methane Information Series 111, p. 3-15.

Jurich, D., and M.A. Adams, 1984, Geologic overview, coal, and coalbed methane resources of Raton Mesa region, in C.T. Rightmire, G.E. Eddy, and J.N. Kirr, eds., Coalbed methane resources of the United States: AAPG Studies in Geology 17, p. 163-184.

Kaiser, W.R., A.R. Scott, and R. Tyler, 1995, Geology and hydrology of coalbed methane producibility in the United States: analogs for the world: Tuscaloosa, Alabama, Intergas ‘95 Short Course, 516 p.Kaiser, W.R., A.R. Scott, D.S. Hamilton, R. Tyler, R.G. McMurry, N. Zhou, and C. M. Tremain, 1994, Geologic and hydrologic controls on coalbed methane: Sand Wash basin, Colorado and Wyoming: Colorado Geological Survey Resource Series 30 (Bureau of Economic Geology, Report of Investigations 220), 151 p.Kaiser, W.R., D.S. Hamilton, A.R. Scott, R. Tyler, and R.J. Finley, 1994, Geological and hydrological controls on the producibility of coalbed methane: Journal of the Geological Society, London, v. 151, part 3, p. 417-420.Kaiser, W.R., D.S. Hamilton, and D.G. Patchen, 1993, Geologic and hydrologic controls on coalbed methane production: Quarterly Review of Methane from Coal Seams Technology, v. 10, no. 3, p. 26-29.Kaiser, W.R., R. Tyler, W.A. Ambrose, A.R. Scott, and D.G. Patchen, 1992, Geologic evaluation of critical production parameters for coalbed methane resources: Quarterly Review of Methane from Coal Seams Technology, v. 9, nos. 3-4, p. 19-24.

Kaji, R., Y. Hishinuma, and Y. Nakamura, 1985, Low temperature oxidation of coals. Effects of pore structure and coal composition: Fuel, v. 64, p. 297-302.Kaji, R., Y. Muranaka, K. Otsuka, and Y. Hishinuma, 1986, Water absorption by coals: effects of pore structure and surface oxygen: Fuel, v. 65, p. 288-291.Kalaitzidis, S., G. Siavalas, N. Skarpelis, C.V. Araujo, and K. Christanis, 2010, Late Cretaceous coal overlying karstic bauxite deposits in the Parnassus-Ghiona Unit, central Greece: coal characteristics and depositional environment: International Journal of Coal Geology, v. 81, p. 211-226.Kalaitzidis, S., H.K. Karapanagioti, K. Christanis, A. Bouzinos, and E. Iliopoulou, 2006, Evaluation of peat and lignite phenanthrene sorption properties in relation to coal petrography: the impact of inertinite: International Journal of Coal Geology, v. 68, p. 30-38.Kalkreuth, W., 1982, Rank and petrographic composition of selected Jurassic-Lower Cretaceous coals of British Columbia, Canada: Bulletin of Canadian Petroleum Geology, v. 30, p. 112-139.Kalkreuth, W., 1982, Rank and petrographic composition of selected Jurassic-Lower Cretaceous coals of British Columbia, Canada: Bulletin of Canadian Petroleum Geology, v. 30, p. 112-139.

Kalkreuth, W., and G. Charnet, 1984, Liquefaction characteristics of selected vitrinite and liptinite rich coals from British Columbia, Canada: Fuel Processing Technology, v. 9, no. 1, p. 53-65.Kalkreuth, W., and G. Macauley, 1984, Organic petrology of selected oil shale samples from the lower Carboniferous Albert Formation, New Brunswick, Canada: Bulletin Canadian Petroleum Geology, v. 32, p. 38-51.Kalkreuth, W., and G. Macauley, 1984, Organic petrology of selected oil shale samples from the Lower Carboniferous Albert Formation, New Brunswick, Canada: Bulletin of Canadian Petroleum Geology, v. 32, p. 38-51.Kalkreuth, W., and G. Macauley, 1984, Organic petrology of selected oil shale samples from the Lower Carboniferous Albert Formation, New Brunswick, Canada: Bulletin of Canadian Petroleum Geology, v. 32, p. 38-51.Kalkreuth, W., and G. Macauley, 1987, Organic petrology and geochemical (Rock Eval) studies on oil shales and coals from the Pictou and Antigonish areas, Nova Scotia, Canada: Bulletin of Canadian Petroleum Geology, v. 35, p. 263-295.Kalkreuth, W., and G. Macauley, 1987, Organic petrology and geochemical (Rock Eval) sutdies on oil shales and coals from the Pictou and Antigonish areas, Nova Scotia, Canada: Bulletin of Canadian Petroleum Geology, v. 35, p. 263-295.Kalkreuth, W., and M. McMechan, 1996, Coal rank and burial history of Cretaceous-Tertiary strata in the Grande Cache and Hinton areas, Alberta, Canada: implications for fossil fuel exploration: Canadian Journal of Sciences, v. 33, p. 938-957.Kalkreuth, W., C. Roy, and M. Hebert, 1986, Vacuum pyrolysis of Canadian Prince mine coal, chemical and petrological analyses of feedcoal and solid residues: Erdöl und Kohle-Erdgas-Petrochemie, v. 39, p. 213-222.

Kalkreuth, W., H. Abercrombie, and K. Burchard, 1994, The coalbed methane potential of Jurassic/Cretaceous coals from the Fernie basin, British Columbia, Canada: Erdol und Kohle - Erdgas - Petrochemie, v. 47, no. 4, p. 134-139.

Kalkreuth, W., M. Lunkes, J. Oliveira, M.L. Ghiggi, E. Osório, K. Souza, C.H. Sampaio, and G. Hidalgo, 2013, The lower and upper coal seams of the Candiota coalfield, Brazil—Geological setting, petrological and chemical characterization, and studies on reactivity and beneficiation related to their combustion potential: International Journal of Coal Geology, v. 111, p. 53-66.Kalkreuth, W., M. Steller, I. Wieschenkamper, and S. Ganz, 1991, Petrographic and chemical characterization of Canadian and German coals in relation to utilization potential. 1. Petrographic and chemical characterization of feedcoals: Fuel, v. 70, p. 683-694.Kalkreuth, W., N. Sherwood, G. Cioccari, Z. Correa da Silva, M. Silva, N. Zhong, and L. Zufa, 2004, The application of FAMM (Fluorescence Alteration of Multiple Macerals) analyses for evaluating rank of Paraná Basin coals, Brazil: International Journal of Coal Geology, v. 57, p. 167-185.Kalkreuth, W., N. Sherwood, G. Cioccari, Z. Corrêa da Silva, M. Silva, N. Zhong, and L. Zufa, 2004, The application of FAMM (Fluorescence Alteration of Multiple Macerals) analyses for evaluating rank of Paraná Basin coals, Brazil: International Journal of Coal Geology, v. 57, p. 167-185.Kalkreuth, W.D., 1982, Rank and petrographic composition of selected Jurassic-Lower Cretaceous coals of British Columbia, Canada: Bulletin of Canadian Petroleum Geology, v. 30, p. 112-139.Kalkreuth, W.D., 2004, Coal facies studies in Canada: International Journal of Coal Geology, v. 58, p. 23-30.Kalkreuth, W.D., D.L. Marchioni, J.H. Calder, M.N. Lamberson, R.D. Naylor, and J. Paul, 1991, The relationship between coal petrography and depositional environments from selected coal basins in Canada: International Journal of Coal Geology, v. 19, p. 21-76.Kalkreuth, W.D., M. Dawson, and J.D. Hughes, 1994, Geological Survey of Canada coalbed methane research - CBM potential of coals from the western Canada sedimentary basin: Newcastle NSW Australia, Twenty Eighth Newcastle Symposium on Advances in the study of the Sydney basin, p. 126-133.

Kanbara, K., T. Hagiwara, A. Shigemi, S. Kondo, Y. Kanayama, K. Wakabayoshi, and N. Hiramoto, 1977, Behavior of coke in a large blast furnace: Transactions of the Iron and Steel Institute of Japan, v. 17, p. 371-380.Kanduč, T., M. Markič, S. Zavšek, and J. McIntosh, 2012, Carbon cycling in the Pliocene Velenje coal basin, Slovenia, inferred from stable carbon isotopes: International Journal of Coal Geology, v. 89, p. 70-83.

Kang, S.M., E. Fathi, R.J. Ambrose, I.Y. Akkutlu, and R.F. Sigal, 2010, Carbon dioxide storage capacity of organic-rich shales: Society of Petroleum Engineers, SPE 134583, 17 p.Kang, S.M., E. Fathi, R.J. Ambrose, I.Y. Akkutlu, and R.F. Sigal, 2010, Carbon dioxide storage capacity of organic-rich shales: Society of Petroleum Engineers, SPE 134583, 17 p.

Kaiser, W.R., 1993, Hydrogeology of coalbed reservoirs, in W.B. Ayers, Jr., W.R. Kaiser, and J.R. Levine, Coal as source rock and gas reservoir: Birmingham, Alabama, 1993 Coalbed Methane Symposium, Short Course 1, p. 188-257.

Kaitano, R., D. Glasser, and D. Hildebrandt, 2007, A laboratory study of a reactive surface layer for the prevention of spontaneous combustion, in G.B. Stracher, ed., Geology of coal fires: case studies from around the world: GSA Reviews in Engineering Geology 18, p. 85-90.

Kalkreuth, W., and D.A. Leckie, 1989, Sedimentological and petrographical characteristics of Cretaceous strandplain coals: a model for coal accumulation from North American western interior seaway, in P.C. Lyons and B. Alpern, eds., Peat and coal: origin, facies and depositional models: International Journal of Coal Geology, v. 12, p. 381-424.

Kalkreuth, W., C. Roy, and M. Steller, 1989, Conversion characteristics of selected Canadian coals based on hydrogenation and pyrolysis experiments, in Contributions to Canadian coal geoscience: Geological Survey of Canada, Paper 89-8, p. 108-114.

Kalkreuth, W., M. Dawson, and D. Hughes, 1995, Geological Survey of Canada coalbed methane research, in J.A. Pajares and J.M.D. Tascon, eds., Coal science: New York, Elsevier, Coal Science and Technology 24, v. 1, p. 31-34.

Kalyoncu, R.S., 2001, Coal combustion products: USGS Minerals Yearbook, v. 1, metals and minerals, p. 19.1-19.5. http://minerals.usgs.gov/minerals/pubs/commodity/coal/Kalyoncu, R.S., and D.W. Olson, 2001, Coal combustion products: USGS Fact Sheet FS 0076-01, 4 p. (http://pubs.usgs.gov/fs/fs076-01/

Kane, J.S., and S.G. Neuzil, 1993, Geochemical and analytical implications of extensive sulfur retention in ash from Indonesian peats, in J.C. Cobb and C.B. Cecil, eds., Modern and ancient coal-forming environments: Geological Society of America Special Paper 286, p. 97-105.

Kantsler, A.J., 1980, Aspects of organic petrology with particular reference to the exinite group of macerals, in A.C. Cook and A.J. Kantsler, eds., Oil shale petrology workshop: Wollongong, Keiraville Kopiers, p. 16-42.

Kantsler, W., and A.C. Cook, 1979, Maturation patterns in the Perth basin: APEA Journal, v. 19, p. 94-107.Karacan, C. Ö., J.P. Ulery, and G.V.R. Goodman, 2008, A numerical evaluation on the effects of impermeable faults on degasification efficiency and methane emissions during underground coal mining: International Journal of Coal Geology, v. 75, p. 195-203.Karacan, C.Ö., 2003, Heterogeneous sorption and swelling in a confined and stressed coal during CO2 injection: Energy and Fuels, v. 17, p. 1595-1605.Karacan, C.Ö., 2007, Swelling-induced volumetric strains internal to a stressed coal associated with CO2 sorption: International Journal of Coal Geology, v. 72, p. 209-220.Karacan, C.Ö., 2009, Forecasting gob gas venthole production performances using intelligent computing methods for optimum methane control in longwall coal mines: International Journal of Coal Geology, v. 79, p. 131-144.Karacan, C.Ö., 2009, Reconciling longwall gob gas reservoirs and venthole production performances using multiple rate drawdown well test analysis: International Journal of Coal Geology, v. 80, p. 181-195.Karacan, C.Ö., 2009, Reservoir rock properties of coal measure strata of the Lower Monongahela Group, Greene County (southwestern Pennsylvania), from methane control and production perspectives: International Journal of Coal Geology, v. 78, p. 47-64.Karacan, C.Ö., 2009, Reservoir rock properties of coal measure strata of the Lower Monongahela Group, Greene County (southwestern Pennsylvania), from methane control and production perspectives: International Journal of Coal Geology, v. 78, p. 47-64.Karacan, C.Ö., 2013, Integration of vertical and in-seam horizontal well production analyses with stochastic geostatistical algorithms to estimate pre-mining methane drainage efficiency from coal seams: Blue Creek seam, Alabama: International Journal of Coal Geology, v. 114, p. 96-113.Karacan, C.Ö., and E. Okandan, 2000, Assessment of energetic heterogeneity of coals for gas adsorption and its effect on mixture predictions for coalbed methane studies: Fuel, v. 79, p. 1963-1974.Karacan, C.Ö., and E. Okandan, 2000, Fracture/cleat analysis of coals from Zonguldak basin (northwestern Turkey) relative to the potential of coalbed methane production: International Journal of Coal Geology, v. 44, p. 109-125.Karacan, C.Ö., and G.D. Mitchell, 2003, Behavior and effect of different coal microlithotypes during gas transport for carbon dioxide sequestration into coal seams: International Journal of Coal Geology, v. 53, p. 201-217.Karacan, C.Ö., and G.D. Mitchell, 2003, Behavior and effect of different coal microlithotypes during gas transport for carbon dioxide sequestration into coal seams: International Journal of Coal Geology, v. 53, p. 201-217.Karacan, C.Ö., and G.V.R. Goodman, 2012, Analyses of geological and hydrodynamic controls on methane emissions experienced in a Lower Kittanning coal mine: International Journal of Coal Geology, v. 98, p. 110-127.Karacan, C.Ö., F.A. Ruiz, M. Cotè, and S. Phipps, 2011, Coal mine methane: a review of capture and utilization practices with benefits to mining safety and to greenhouse gas reduction: International Journal of Coal Geology, v. 86, p. 121-156.Karacan, C.Ö., G.S. Esterhuizen, S.J. Schatzel, and W.P. Diamond, 2007, Reservoir simulation-based modeling for characterizing longwall methane emissions and gob gas venthole production: International Journal of Coal Geology, v. 71, p. 225-245.Karacan, C.Ö., G.S. Esterhuizen, S.J. Schatzel, and W.P. Diamond, 2007, Reservoir simulation-based modeling for characterizing longwall methane emissions and gob gas venthole production: International Journal of Coal Geology, v. 71, p. 225-245.Karacan, C.Ö., R.A. Olea, and G. Goodman, 2012, Geostatistical modeling of the gas emission zone and its in-place gas content for Pittsburgh-seam mines using sequential Gaussian simulation: International Journal of Coal Geology, v. 90-91, p. 50-71.Karacan, C.Ö., W.P. Diamond, and S.J. Schatzel, 2007, Numerical analysis of the influence of in-seam horizontal methane drainage boreholes on longwall face emission rates: International Journal of Coal Geology, v. 72, p. 15-32.Kara-Gülbay, R., and S. Korkmaz, 2013, Organic geochemistry of the asphaltite occurrences in the Gümüşhacikőy (Amasya) area, northern Turkey: Fuel, v. 107, p. 74-83.Karaoulis, M., A. Revil, and D. Mao, 2014, Localization of a coal seam fire using combined self-potential and resistivity data: International Journal of Coal Geology, v. 128-129, p. 109-118.Karas, J., R.J. Pugmire, W.R. Woolfenden, D.M. Grant, and S. Blair, 1985, Comparison of physical and chemical properties of maceral groups separated by density gradient centrifugation: International Journal of Coal Geology, v. 5, p. 315-318.Karayigit, A.I., D.A. Spears, and C.A. Booth, 2000, Antimony and arsenic anomalies in the coal seams from the Gokler coalfield, Gediz, Turkey: International Journal of Coal Geology, v. 44, p. 1-17.Karayigit, A.I., R.A. Gayer, X. Querol, and T. Onacak, 2000, Contents of major and trace elements in feed coals from Turkish coal-fired power plants: International Journal of Coal Geology, v. 44, p. 169-184.Karayigit, A.I., T. Onacak, R.A. Gayer, and S. Goldsmith, 2001, Mineralogy and geochemistry of feed coals and their combustion residues from the Cayirhan power plant, Ankara, Turkay: Applied Geochemistry, v. 16, p. 911-919.Karr, C.K., Jr., ed., 1978, Analytical methods for coal and coal products, v. 1: New York, Academic Press, 580 p.Karr, C.K., Jr., ed., 1978, Analytical methods for coal and coal products, v. 2: New York, Academic Press, 669 p.Karr, C.K., Jr., ed., 1979, Analytical methods for coal and coal products, v. 3: New York, Academic Press, 641 p.Karrick, L.C., 1926, Manual of testing methods for oil shale and shale oil: U.S. Bureau of Mines Bulletin 249.Kasperski, K.L., Y. Briker, D.P. Deshpande, and B. Ozüm, 1996, Coal-oil agglomeration and combustion studies for a bituminous coal pond tailing: Energy Sources, v. 18, p. 43-50.Kattai, V., and U. Lokk, 1998, Historical review of the kukersite oil shale exploration in Estonia: Oil Shale, v. 15, p. 102-110.Katz, B.J., 1983, Limitations of ‘Rock-Eval’ pyrolysis for typing organic matter: Organic Geochemistry, v. 4, p. 195-199.Katz, B.J., 1994, An alternative view on Indo-Australian coals as a source of petroleum: APEA Journal, v. 34, p. 256-267.

Katz, B.J., R.N. Pheifer, and D.J. Schunk, 1988, Interpretation of discontinuous vitrinite reflectance profiles: AAPG Bulletin, v. 72, p. 926-931.Keating, E.H., J.A. Hakala, H. Viswanathan, J.W. Carey, R. Pawar, G.D. Guthrie, and J. Fessenden-Rahn, 2013, CO2 leakage impacts on shallow groundwater: Field-scale reactive-transport simulations informed by observations at a natural analog site: Applied Geochemistry, v. 30, p. 136-147.Kędzior, S., 2009, Accumulation of coal-bed methane in the south-west part of the Upper Silesian coal basin (southern Poland): International Journal of Coal Geology, v. 80, p. 20-34.Kędzior, S., 2011, The occurrence of a secondary zone of coal-bed methane in the southern part of the Upper Silesian coal basin (southern Poland): Potential for methane exploitation: International Journal of Coal Geology, v. 86, p. 157-168.Kędzior, S., and I. Jelonek, 2013, Reservoir parameters and maceral composition of coal in different Carboniferous lithostratigraphical series of the Upper Silesian coal basin, Poland: International Journal of Coal Geology, v. 111, p. 98-105.Kędzior, S., M.J. Kotarba, and Z. Pękała, 2013, International Journal of Coal Geology, v. 105, p. 24-35.Keim, S.A., K.D. Luxbacher, and M. Karmis, 2011, A numerical study on optimization of multilateral horizontal wellbore patterns for coalbed methane production in southern Shanxi Province, China: International Journal of Coal Geology, v. 86, p. 306-317.

Katz, B.J., P.A. Kelley, R.A. Royle, and T. Jorjorian, 1991, Hydrocarbon products of coals as revealed by pyrolysis-gas chromatography, in P.K. Mukhopadhyay, M.G. Fowler, and W.G. Dow, eds., Selected papers from the symposium on coal and terrestrial organic matter as a source rock for petroleum: Organic Geochemistry, v. 17, p. 711-722.

Kekisheva, L., N. Krainyukova, Y. Zhirjakov, and J. Soone, 2004, A review of basic methods of extraction of neutral oxygen compounds from shale oil, their composition and properties: Oil Shale, v. 21, p. 173-178.Kelemen, S.R., and L.M. Kwiatek, 2009, Physical properties of selected block Argonne Premium bituminous coal related to CO2, CH4, and N2 adsorption: International Journal of Coal Geology, v. 77, p. 2-9.Kelemen, S.R., C.C. Walters, P.J. Kwiatek, H. Freund, M. Afeworki, M. Sansone, W.A. Lamberti, R.J. Pottorf, H.G. Machel, K.E. Peters, and T. Bolin, 2010, Characterization of solid bitumens originating from thermal chemical alteration and thermochemical sulfate reduction: Geochimica et Cosmochimica Acta, v. 74, p. 5305-5332.Kelloway, S., C.R. Ward, C.E. Marjo, I.E. Wainwright, and D.R. Cohen, 2014, Quantitative chemical profiling of coal using core-scanning X-ray fluorescence techniques: International Journal of Coal Geology, v. 128-129, p. 55-67. (elements)Kelso, B.S., 1994, Geologic controls on open-hole cavity completions in the San Juan basin: Quarterly Review of Methane from Coal Seams Technology, v. 11, nos. 3 & 4, p. 1-6.Kelso, B.S., and J.A. Kelafant, 1989, A strategy for coalbed methane production development part I: geologic characterization: Proceedings of the 1989 Coalbed Methane Symposium, paper 8911, p. 3-9.Kelso, B.S., T.E. Lombardi, and J.A. Kuuskraa, 1996, Drilling and production statistics for major U.S. coalbed methane and gas shale reservoirs: Des Plaines, Illinois, Gas Technology Institute, Report GRI-96/0052, 59 p.

Kemp, A.E.S., G.H.J. Oliver, and J.R. Baldwin, 1985, Low-grade metamorphism and accretion tectonics: southern uplands terrain, Scotland: Mineralogical Magazine, v. 49, p. 335-344.

Kent, R.W., N.C. Ghose, P.R. Paul, M.J. Hassan, and A.D. Saunders, 1992, Coal-magma interaction: an integrated model for the emplacement of cylindrical intrusions: Geological Magazine, v. 129, p. 753-762.Keogh, R.A., D.N. Taulbee, J.C. Hower, B. Chawla, and B.H. Davis, 1992, Liquefaction characteristics of the three major maceral groups separated from a single coal: Energy & Fuels, v. 6, p. 614-618.Kerp, H., 1990, The study of fossil gymnosperm cuticles by means of cuticular analysis: Palaios, v. 5, p. 548-569.Kerp, H., and M. Barthel, 1993, Problems of cuticular analysis of pteridosperms: Review of Palaeobotany and Palynology, v. 78, p. 1-18.Kessler, M.F., 1973, Interpretation of the chemical composition of bituminous coal macerals: Fuel, v. 52, p. 191-197.Ketris, M.P., and Y.E. Yudovich, 2009, Estimations of Clarkes for Carbonaceous biolithes: World averages for trace element contents in black shales and coals: International Journal of Coal Geology, v. 78, p. 135-148.Khalimov, E.M., I.M. Klimushin, L.I. Ferdman, and I.S. Gol’dberg, 1985, Geological factors in the formation of deposits of natural bitumens: International Geology Review, v. 27, p. 187-193.

Khanchuk, A.I., V.V. Ivanov, M.G. Blokhin, and N.V. Zarubina, 2013, Coal deposits as promising sources of lithium: TSOP Newsletter, v. 30, no. 4, p. 13-15.Khandelwal, A., and H.P. Gupta, 1993, Organodebris analysis of Chilka Lake, Orissa, India: an assessment of depositional environment: Palaeobotanist, v. 42, p. 215-224.Khandelwal, M., and T.N. Singh, 2010, Prediction of macerals contents of Indian coals from proximate and ultimate analyses using artificial neural networks: Fuel, v. 89, p. 1101-1109.Khandelwal, M., and T.N. Singh, 2010, Prediction of macerals contents of Indian coals from proximate and ultimate analyses using artificial neural networks: Fuel, v. 89, p. 1101-1109.Kharaka, Y.K., D.R. Cole, J.J. Thordsen, E. Kakouros, and H.S. Nance, 2006, Gas-water-rock interactions in sedimentary basins: CO2 sequestration in the Frio Formation, Texas, USA: Journal of Geochemical Exploration, v. 89, p. 183-186.Kharaka, Y.K., J.J. Thordsen, S.D. Hovorka, H.S. Nance, D.R. Cole, T.J. Phelps, and K.G. Knauss, 2009, Potential environmental issues of CO2 storage in deep saline aquifers: Geochemical results from the Frio-I brine pilot test, Texas, USA: Applied Geochemistry, v. 24, p. 1106-1112.

Khavari-Khorasani, G., 1983, Structure of albertite from New Brunswick, Canada: Bulletin of Canadian Petroleum Geology, v. 31, p. 123-126.Khavari-Khorasani, G., and D.G. Murchison, 1978, Thermally metamorphosed bitumen from Windy Knoll, Derbyshire, England: Chemical Geology, v. 22, p. 91-105.

Khavari-Khorasani, G., H.E. Blayden, and D.G. Murchison, 1978, Refractive index and absorption coefficients as measures of structural organization in carbonized bitumen: Journal of Microscopy, v. 114, p. 199-204.Khavari-Khorasani, G., H.E. Blayden, and D.G. Murchison, 1979, Microscope photometry in studies of the molecular structure of carbonized bitumens and pyrobitumens: Journal of Microscopy, v. 116, p. 337-349.Khodaverdian, M., J. McLennan, I. Palmer, and H. Vaziri, 1996, Coalbed cavity completion analysis suggests improvements: Gas Tips, v. 2, no. 1, p. 22-30.Khodaverdian, M.F., 1994, Coalbed methane stimulation techniques: Mechanisms and applicability: Gas Research Institute, Topical Report, GRI-95/0003, 97 p.Khorasani, G.K., 1987, Novel development in fluorescence microscopy of complex organic mixtures: application in petroleum geochemistry: Organic Geochemistry, v. 11, p. 157-168.

Khorasani, G.K., 1989, Factors controlling source rock potential of the Mesozoic coal-bearing strata from offshore central Norway: application to petroleum exploration: Bulletin of Canadian Petroleum Geology, v. 37, p. 417-427.Khorasani, G.K., and D.G. Murchison, 1988, Order of generation of petroleum hydrocarbons from liptinite macerals with increasing thermal maturity: Fuel, v. 67, p. 1160-1162.Khorasani, G.K., and D.G. Murchison, 1988, Order of generation of petroleum hydrocarbons from liptinitic macerals with increasing thermal maturity: Fuel, v. 67, p. 1160-1162.Khorasani, G.K., and D.G. Murchison, 1988, Order of generation of the petroleum hydrocarbons from liptinitic macerals with increasing thermal maturity: Fuel, v. 67, p. 1160-1162.Khorasani, G.K., and J.K. Michelsen, 1991, Geological and laboratory evidence for early generation of large amounts of liquid hydrocarbons from suberinite and subereous components: Organic Geochemistry, v. 17, p. 849-863.

Khorasani, G.K., and J.K. Michelsen, 1992, Primary alteration-oxidation of marine algal organic matter from oil source rocks of the North Sea and Norwegian Arctic: new findings: Organic Geochemistry, v. 19, p. 327-343.

Kelso, B.S., W.G. Leel, Jr., and D.L. Carr, 1991, Coalbed methane resource and producibility potential of the Rock Springs Formation, Great Divide Basin, Wyoming, in S.D. Schwochow, D.K. Murray, and M.F. Fahy, eds., Coalbed methane of western North America: Denver, CO, Rocky Mountain Association of Geologists Guidebook, p. 201-208.

Kemp, J.H., and K.M. Petersen, 1988, Coal-bed gas development in the San Juan basin: a primer for the lawyer and landman, in J.E. Fassett, ed., Geology and coal-bed methane resources of the northern San Juan basin, Colorado and New Mexico: Denver, Rocky Mountain Association of Geologists Guidebook, p. 257-279.

Khan, M.R., and R.G. Jenkins, 1989, Influence of weathering and low-temperature oxidation on the thermoplastic properties of coal, in C.R. Nelson, ed., Chemistry of coal weathering: New York, Elsevier Science Publishers, Coal Science and Technology, v. 14, p. 107-132.

Khavari Khorasani, G., and J.K. Michelsen, 1993, The thermal evolution of solid bitumens, bitumen reflectance, and kinetic modeling of reflectance: application in petroleum and ore prospecting, in F. Goodarzi and R.W. Macqueen, eds., Geochemistry and petrology of bitumen with respect to hydrocarbon generation and mineralization: Energy Sources, v. 15, p. 181-204.

Khavari-Khorasani, G., and J.K. Michelsen, 1999, Coal bed gas content and gas undersaturation, in M. Mastalerz, M. Glikson, and S.D. Golding, eds., Coalbed methane: scientific, environmental and economic evaluation: Boston, Kluwer Academic Publishers, p. 207-231.

Khorasani, G.K., 1987, Oil-prone coals of the Walloon coal measures, Surat basin, Australia, in A.C. Scott, ed., Coal and coal-bearing strata: recent advances: London, The Geological Society Special Publication 32, p. 303-310.

Khorasani, G.K., and J.K. Michelsen, 1992, Primary alteration-oxidation of marine algal organic matter from oil source rocks of the North Sea and Norwegian Arctic: new findings, in C.B. Eckardt, J.R. Maxwell, S.R. Larter, and D.A.C. Manning, eds., Advances in organic geochemistry 1991, part II. advances and applications in energy and the natural environment: Organic Geochemistry, v. 19, p. 327-343.

Khorasani, G.K., and J.K. Michelsen, 1994, Four-dimensional fluorescence imaging of oil generation: development of a new fluorescence imaging technique: Organic Geochemistry, v. 22, p. 211-223.Khorasani, G.K., and J.K. Michelsen, 1994, The effects of overpressure, lithology, chemistry and heating rate on vitrinite reflectance evolution, and its relationship with oil generation: APEA Journal, v. 34, part 1, p. 418-434.Khorasani, G.K., and J.K. Michelsen, 1994, The effects of overpressure, lithology, chemistry and heating rate on vitrinite reflectance evolution, and its relationship with oil generation: APEA Journal, v. 34, pt. 1, p. 418-434.Khorasani, G.K., and J.K. Michelsen, 1994, The effects of overpressure, lithology, chemistry and heating rate on vitrinite reflectance evolution, and its relationship with oil generation: APEA Journal, v. 34, pt. 1, p. 418-434.Khorasani, G.K., D.G. Murchison, and A.C. Raymond, 1990, Molecular disordering in natural cokes approaching dike and sill contacts: Fuel, v. 69, p. 1037-1045.Khosrokhavar, R., K.-H. Wolf, and H. Bruining, 2014, Sorption of CH4 and CO2 on a carboniferous shale from Belgium using a manometric setup: International Journal of Coal Geology, v. 128-129, p. 153-161.Khosrokhavar, R., K.-H. Wolf, and H. Bruining, 2014, Sorption of CH4 and CO2 on a carboniferous shale from Belgium using a manometric setup: International Journal of Coal Geology, v. 128-129, p. 153-161.Kidd, J.T., B.S. Camp, L.K. Lottman-Craig, T.E. Osborne, J.L. Smith, J.L. Saulsberry, P.F. Steidl, and P.B. Stubbs, 1992, Geologic manual for the evaluation and development of coalbed methane: GRI Topical Report GRI 91-0110, 110 p.Kiessling, F.J., 1981, Alternatives to conventional cokemaking and consuming practices: Society of Mining Engineers of AIME, Transactions v. 270, p. 1247-1250.

Kilby, W.E., 1985, Biaxial reflecting coals in the Peace River coalfield: British Columbia Ministry of Energy, Mines and Petroleum Resources, Geological Fieldwork, 1985, Paper 1986-1, p. 127-133.Kilby, W.E., 1988, Recognition of vitrinite with non-uniaxial negative reflectance characteristics: International Journal of Coal Geology, v. 9, p. 267-285.Kilby, W.E., 1991, Vitrinite reflectance measurement -- some technique enhancements and relationships: International Journal of Coal Geology, v. 19, p. 201-218.Kilby, W.E., 1991, Vitrinite reflectance measurement -- some technique enhancements and relationships: International Journal of Coal Geology, v. 19, p. 201-218.Killops, S., D. Jarvie, R. Sykes, and R. Funnell, 2002, Maturity-related variation in the bulk-transformation kinetics of a suite of compositionally related New Zealand coals: Marine and Petroleum Geology, v. 19, p. 1151-1168.Killops, S., D. Jarvie, R. Sykes, and R. Funnell, 2002, Maturity-related variation in the bulk-transformation kinetics of a suite of compositionally related New Zealand coals: Marine and Petroleum Geology, v. 19, p. 1151-1168.Killops, S., P. Walker, and D. Wavrek, 2001, Maturity-related variations in the bitumen compositions of coals from Tara-1 and Toko-1 wells: New Zealand Journal of Geology & Geophysics, v. 44, p. 157-169.Killops, S.D., A.D. Woolhouse, R.J. Weston, and R.A. Cook, 1994, A geochemical appraisal of oil generation in the Taranaki basin, New Zealand: AAPG Bulletin, v. 78, p. 1560-1585.Killops, S.D., and V.J. Killops, 1993, An introduction to organic geochemistry: Longman Scientific and Technical, 265 p.Killops, S.D., N. Mills, and P.E. Johansen, 2008, Pyrolytic assessment of oil generation and expulsion from a suite of vitrinite-rich New Zealand coals: Organic Geochemistry, v. 39, p. 1113-1118.Killops, S.D., R.H. Funnell, R.P. Suggate, R. Sykes, K.E. Peters, C. Walters, A.D. Woolhouse, R.J. Weston, and J.-P. Boudou, 1998, Predicting generation and expulsion of paraffinic oil from vitrinite-rich coals: Organic Geochemistry, v. 29, p. 1-21.

Kim, A.G., 1973, The composition of coalbed gas: U.S. Bureau of Mines Report of Investigations 7762, 9 p.Kim, A.G., 1974, Low-temperature evolution of hydrocarbon gases from coal: U.S. Bureau of Mines Report of Investigations 7965, 23 p.Kim, A.G., 1974, Methane in the Pittsburgh coalbed, Washington County, Pa.: U.S. Bureau of Mines Report of Investigations 7969, 16 p.Kim, A.G., 1975, Methane in the Pittsburgh coalbed, Greene County, Pa.: U.S. Bureau of Mines Report of Investigations 8026, 10 p.Kim, A.G., 1977, Estimating methane content of bituminous coalbeds from adsorption data: U.S. Bureau of Mines Report of Investigations 8245, 22 p.Kim, A.G., 1977, Laboratory studies on spontaneous heating of coal: U.S. Bureau of Mines, Information Circular 8756, 13 p.Kim, A.G., 1978, Experimental studies on the origin and accumulation of coalbed gas: U.S. Bureau of Mines Report of Investigations 8317, 18 p.Kim, A.G., 1995, Relative self-heating tendencies of coal, carbonaceous shales, and coal refuse: U.S. Bureau of Mines, Report of Investigations 9537, 21 p.Kim, A.G., 2001, Utilization of coal combustion by-products: determining the environmental safety: Energeia, v. 12, no. 2, p. 1-4.

Kim, A.G., and L.J. Douglas, 1972, Hydrocarbon gases produced in a simulated swamp environment: U.S. Bureau of Mines Report of Investigations 7690, 15 p.Kim, A.G., and L.J. Douglas, 1973, Gases desorbed from five coals of low gas content: U.S. Bureau of Mines Report of Investigations 7768, 9 p.Kim, D., R.P. Philp, and R.P. Sorenson, 2010, Geochemical characterization of solid bitumen in the Chesterian (Mississippian) sandstone reservoir of the Hitch field, southwest Kansas: AAPG Bulletin, v. 94, p. 1031-1057.Kimura, T., H. Kawashima, and I. Saito, 1994, Smectite and illite/smectite mixed-layer clay minerals in the Ashibetsu clays: International Journal of Coal Geology, v. 26, p. 215-231.

King, L.H., 1963, On the origin of anthraxolite and impsonite: Canada Department of Mines and Technical Surveys, Mines Branch Research Report R 116, 9 p.King, L.H., 1963, Origin of Albert mines oil shale (New Brunswick), and its associated albertite: Canada Department of Mines, Branch Report F 115, 26 p.

Khorasani, G.K., and J.K. Michelsen, 1993, The thermal evolution of solid bitumens, bitumen reflectance, and kinetic modeling of reflectance: application in petroleum and ore prospecting, in F. Goodarzi and R.W. Macqueen, eds., Geochemistry and petrology of bitumen with respect to hydrocarbon generation and mineralization: Energy Sources, v. 15, p. 181-204.

Kilborn, G.R., 1964, New methods of mining and refining gilsonite, in E.F. Sabatka, ed., Guidebook to the geology and mineral resources of the Uinta basin: Intermountain Association of Petroleum Geologists, 13 th annual field conference, p. 247-252.

Killops, S.D., R.M.K. Carlson, and K.E. Peters, 2000, High-temperature GC evidence for the early formation of C 40+ n-alkanes in coals: Organic Geochemistry, v. 31, p. 589-597.

Kim, A.G., 2007, Greenhouse gases generated in underground coal-mine fires, in G.B. Stracher, ed., Geology of coal fires: case studies from around the world: GSA Reviews in Engineering Geology 18, p. 1-13.Kim, A.G., and F.N. Kissell, 1988, Methane formation and migration in coalbeds, in M. Deul and A.G. Kim, Methane control research: summary of results, 1964-80: U.S. Bureau of Mines Bulletin 687, p. 18-25.

King, H.M., and J.J. Renton, 1979, The mode of occurrence and distribution of sulfur in West Virginia coals, in A.C. Donaldson, M.W. Presley, and J.J. Renton, eds., Carboniferous coal short course and guidebook: West Virginia Geological and Economic Survey, Bulletin B-37-1, p. 278-301.

King, L.H., F.E. Goodspeed, and D.S. Montgomery, 1963, A study of sedimented organic matter and its natural derivatives: Canada Department of Mines and Technical Surveys, Ottawa, Mines Branch Research Report R 114, 62 p.Kinghorn, R.R.F., and M. Rahman, 1980, The density separation of different maceral groups of organic matter dispersed in sedimentary rocks: Journal of Petroleum Geology, v. 2, p. 449-454.Kinghorn, R.R.F., and M. Rahman, 1980, The density separation of different maceral groups of organic matter dispersed in sedimentary rocks: Journal of Petroleum Geology, v. 2, p. 499-554.Kinghorn, R.R.F., and M. Rahman, 1983, Specific gravity as a kerogen type and maturation indicator with special reference to amorphous kerogen: Journal of Petroleum Geology, v. 6, p. 179-194.Kinnon, E.C.P., S.D. Golding, C.J. Boreham, K.A. Baublys, and J.S. Esterle, 2010, Stable isotope and water quality analysis of coal bed methane production waters and gases from the Bowen Basin, Australia: International Journal of Coal Geology, v. 82, p. 219-231.Kinnon, E.C.P., S.D. Golding, C.J. Boreham, K.A. Baublys, and J.S. Esterle, 2010, Stable isotope and water quality analysis of coal bed methane production waters and gases from the Bowen Basin, Australia: International Journal of Coal Geology, v. 82, p. 219-231.Kirchner, A.T., 1987, Evaluative report on the mechanical properties of coke: IEA Coal Research, IEACR/04, 25 p.Kirkland, D.W., T.-F. Tsui, and M.L. Stockton, 1987, Generation of oil from coal and carbonaceous shale (abstract): AAPG Bulletin, v. 71, p. 577.Kirschner, J.P., and D.A. Barnes, 2009, Geological sequestration capacity of the Dundee Limestone, Michigan Basin, United States: Environmental Geosciences, v. 16, no. 3, p. 127-138.

Kissell, F.N., 1972, The methane migration and storage characteristics of the Pittsburgh, Pocahontas no. 3, and Oklahoma Hartshorne coalbeds: U.S. Bureau of Mines Report of Investigations 7667, 22 p.Kissell, F.N., and J.C. Edwards, 1975, Two-phase flow in coalbeds: U.S. Bureau of Mines, Report of Investigations 8066, 16 p.Kissell, F.N., C.M. McCulloch, and C.H. Elder, 1973, The direct method of determining methane content of coalbeds for ventilation design: U.S. Bureau of Mines Report of Investigations 7767, 17 p.Kister, J., M. Guiliano, G. Mille, and H. Dou, 1988, Changes in the chemical structure of low rank coal after low temperature oxidation or demineralization by acid treatment: Fuel, v. 67, p. 1076-1081.Kitamura, K., H. Iwakiri, T. Kamijo, and K. Narita, 1982, Improvement of coke quality by addition of several binders: Iron and Steel Society Conference Proceedings, v. 49, p. 424-429.Kiyama, T., S. Nishimoto, M. Fujioka, Z. Xue, Y. Ishijima, Z. Pan, and L.D. Connell, 2011, Coal swelling strain and permeability change with injecting liquid/supercritical CO2 and N2 at stress-constrained conditions: International Journal of Coal Geology, v. 85, p. 56-64.

Klauke, F., A. Reidick, and K.D. Tigges, 2003, Successful generation: World Coal, v. 12, p. 51-53. (reduce CO2 emissions)

Klein, D.A., R.M. Flores, C. Venot, K. Gabbert, R. Schmidt, G.D. Stricker, A. Pruden, and K. Mandernack, 2008, Molecular sequences derived from Paleocene Fort Union Formation coals vs. associated produced waters: Implications for CBM regeneration: International Journal of Coal Geology, v. 76, p. 3-13.Klein, D.A., R.M. Flores, C. Venot, K. Gabbert, R. Schmidt, G.D. Stricker, A. Pruden, and K. Mandernack, 2008, Molecular sequences derived from Paleocene Fort Union Formation coals vs. associated produced waters: Implications for CBM regeneration: International Journal of Coal Geology, v. 76, p. 3-13.Klein, G. D., 1990, Pennsylvanian time scales and cycle periods: Geology, v. 18, p. 455-457. (comments in v. 19 p. 405-410)Klein, G. D., 1992, Climatic and tectonic sea-level gauge for Midcontinent Pennsylvanian cyclothems: Geology, v. 20, p. 363-366.Klein, G. D., and D.A. Willard, 1989, Origin of the Pennsylvanian coal-bearing cyclothems of North America: Geology, v. 17, p. 152-155. (comment and reply in v. 17, p. 871-872)Klein, G. D., and J.B. Kupperman, 1992, Pennsylvanian cyclothems: methods of distinguishing tectonically induced changes in sea level from climatically induced changes: Geological Society of America Bulletin, v. 104, p. 166-175.Klein, G.D., 1993, Paleoglobal change during deposition of cyclothems: calculating the contributions of tectonic subsidence, glacial eustasy and long-term climate influences on Pennsylvanian sea-level change: Tectonophysics, v. 222, p. 333-360.

Klein, R., and R. Wellek, eds., 1989, Sample selection, aging, and reactivity of coal: New York, John Wiley & Sons, 469 p.Klein, R., and R. Wellek, eds., Sample selection, aging, and reactivity of coal: New York, John Wiley & Sons, 469 p.Klubov, B.A., 1993, A new scheme for the formation and classification of bitumens: Journal of Petroleum Geology, v. 16, p. 335-344.

Klusman, R.W., 2003, A geochemical perspective and assessment of leakage potential for a mature carbon dioxide–enhanced oil recovery project and as a prototype for carbon dioxide sequestration; Rangely field, Colorado: AAPG Bulletin, v. 87, p. 1485-1507.Klusman, R.W., 2003, Computer modeling of methanotrophic oxidation of hydrocarbons in the unsaturated zone from an enhanced oil recovery/sequestration project, Rangely, Colorado, USA: Applied Geochemistry, v. 18, p. 1839-1852.Klusman, R.W., 2003, Rate measurements and detection of gas microseepage to the atmosphere from an enlarged oil recovery/sequestration project, Rangely, Colorado, USA: Applied Geochemistry, v. 18, p. 1825-1838.Klusman, R.W., 2005, Baseline studies of surface gas exchange and soil-gas composition in preparation for CO2 sequestration research: Teapot Dome, Wyoming: AAPG Bulletin, v. 89, p. 981-1003.Knaus, E., and J. Killen, 2009, Oil shale—conclusion. Technology may control adverse environmental effects: Oil & Gas Journal, v. 107.6, p. 42-45.

Knox, L.M., and J. Hadro, 2001, Canister desorption techniques: variation and reliability: Tuscaloosa, Alabama, Proceedings, International Coalbed Methane Symposium, Paper 123, p. 319-329.Koch, J., 1970, Frequency distributions of vitrinite reflectance values and vitrinites distinguishable by reflectance: Erdol und Kohle-Erdgas-Petrochemie, v. 23, no. 1, p. 2-6.

Kirste, D., M.G. Fowler, F. Goodarzi, and R.W. Macqueen, 1989, Optical and compositional characters and paleothermal implications of a diverse suite of natural bitumens from Middle Devonian carbonate rocks, Pine Point, Northwest Territories, in Current research, part G: Geological Survey of Canada, Paper 89-1G, p. 51-55.

Kizgut, S., N. Miles, and M. Cloke, 1995, Production of coal maceral concentrates by flotation, in J.A. Pajares and J.M.D. Tascón, eds., Coal science, v. 2: New York, Elsevier, Coal Science and Technology 24, p. 1553-1556.Klasson, K.T., M.D. Ackerson, E.C. Clausen, and J.L. Gaddy, 1993, Direct bacterial conversion of coal to liquid fuels, in D.L. Crawford, ed., Microbial transformations of low rank coals: Baco Raton, CRC Press, p. 93-110.

Kleesattel, D.R., 1984, Distribution, abundance, and maceral content of the lithotypes in the Beulah-Zap bed of North Dakota, in R.L. Houghton and E.N. Clausen, eds., 1984 Symposium on the Geology of Rocky Mountain Coal: North Dakota Geological Society, Publication 84-1, p. 28-40.Klein, A., K. Buck and S. Ruhl, 2004, Helper field: An integrated approach to coalbed methane development, Uinta Basin, Utah: AAPG Studies in Geology 50, p.541-550.

Klein, G.D., 1994, Depth determination and quantitative distinction of the influence of tectonic subsidence and climate on changing sea level during deposition of Midcontinent Pennsylvanian cyclothems, in J.M. Dennison and F.R. Ettensohn, eds., Tectonic and eustatic controls on sedimentary cycles: SEPM Concepts in Sedimentology and Paleontology, v. 4, p. 35-50.

Klug, C.R., and J.T. Schabilion, 1992, A Devonian paper coal (cutinite) in the Lithograph City Formation at Garrison, Iowa, in J. Day and B.J. Bunker, eds., The stratigraphy, paleontology, depositional and diagenetic history of the Middle-Upper Devonian Cedar Valley Group of central and eastern Iowa: Iowa Geological Survey Guidebook 16, p. 147-158.

Knight, J.L., B.J. Shevlin, D.C. Edgar, and P. Dolan, 1996, Coal thickness distributions on the UK continental shelf, in R. Gayer and I. Harris, eds., Coalbed methane and coal geology: London, Geological Society Special Publication 109, p. 43-57.

Koch, J., 1997, Organic petrographic investigations of the Kupferschiefer in northern Germany: International Journal of Coal Geology, v. 33, p. 301-316. (bituminite)Koen, A.D., 1991, U.S. tax credits spurring coal seam, tight sands boom amid controversy: Oil & Gas Journal, v. 89, no. 41, p. 19-24.Koenig, R.A., and G.J. Bell, 1985, Design of single phase flow tests for water-saturated coalbed methane reservoirs: Gas Research Institute, Quarterly Review of Methane from Coal Seams Technology, v. 3, no. 1, p. 17-22.

Kohli, K.B., N.J. Thomas, B.N. Prabhu, and K.N. Misra, 1994, Simulated petroleum generation studies by hydrous pyrolysis of a Tertiary coal from northern Cambay basin of India: Organic Geochemistry, v. 21, p. 323-332.Kojima, K., T. Nishi, T. Yamaguchi, H. Nakama, and S. Ida, 1977, Changes in the properties of coke in blast furnace: Transactions of the Iron and Steel Institute of Japan, v. 17, p. 402-409.Kolak, J.J., and R.C. Burruss, 2006, Geochemical investigation of the potential for mobilizing non-methane hydrocarbons during carbon dioxide storage in deep coal beds: Energy and Fuels, v. 20, p. 566-574.Kolker, A., 2012, Minor element distribution in iron disulfides in coal: A geochemical review: International Journal of Coal Geology, v. 94, p. 32-43.Kolker, A., 2012, Minor element distribution in iron disulfides in coal: A geochemical review: International Journal of Coal Geology, v. 94, p. 32-43.Kolker, A., and C.-L. Chou, 1994, Cleat-filling calcite in Illinois Basin coals: trace-element evidence for meteoric fluid migration in a coal basin: Journal of Geology, v. 102, p. 111-116.

Kolker, A., B.S. Panov, Y.B. Panov, E.R. Landa, K.M. Conko, V.A. Korchemagin, T. Shendrik, and J.D. McCord, 2009, Mercury and trace element contents of Donbas coals and associated mine water in the vicinity of Donetsk, Ukraine: International Journal of Coal Geology, v. 79, p. 83-91.Kolker, A.., C.L. Senior, and J.C. Quick, 2006, Mercury in coal and the impact of coal quality on mercury emissions from combustion systems: Applied Geochemistry, v. 21, p. 1821-1836.Kolker, A.., C.L. Senior, and J.C. Quick, 2006, Mercury in coal and the impact of coal quality on mercury emissions from combustion systems: Applied Geochemistry, v. 21, p. 1821-1836.Komorek, J., and R. Morga, 2002, Relationship between the maximum and the random reflectance of vitrinite for coal from the Upper Silesian coal basin (Poland): Fuel, v. 81, p. 969-971.Komorek, J., and R. Morga, 2003, Vitrinite reflectance property change during heating under inert conditions: International Journal of Coal Geology, v. 54, p. 125-136.Komorek, J., and R. Morga, 2007, Evolution of optical properties of vitrinite, sporinite and semifusinite in response to heating under inert conditions: International Journal of Coal Geology, v. 71, p. 389-404.Komorek, J., and R. Morga, 2007, Evolution of optical properties of vitrinite, sporinite and semifusinite in response to heating under inert conditions: International Journal of Coal Geology, v. 71, p. 389-404.

Komraus, J.L., and E.S. Popiel, 1992, Investigations of iron compounds in coal, application of the Mossbauer Spectroscopy: Erdol und Kohle-Erdgas-Petrochemie, v. 45, p. 264-269.Koperna, G., D. Riestenberg, V. Kuuskraa, R. Rhudy, R. Trautz, G.R. Hill, and R. Esposito, 2012, The SECARB anthropogenic test: A US integrated CO2 capture, transportation and storage test: International Journal of Clean Coal and Energy, v. 1, p. 13-26.

Kopp, O.C., M.E. Bennett III, and C.E. Clark, 2000, Volatiles lost during coalification: International Journal of Coal Geology, v. 44, p. 69-84.Kopp, O.C., M.E. Bennett, III, and C.E. Clark, 2000, Volatiles lost during coalification: International Journal of Coal Geology, v. 44, p. 69-84.Kopyscinski, J., T.J. Schildhauer, and S.M.A. Biollaz, 2010, Review article: Production of synthetic natural gas (SNG) from coal and dry biomass – a technology review from 1950 to 2009: Fuel, v. 89, p. 1763-1783.

Kortenski, J., 1992, Carbonate minerals in Bulgarian coals with different degrees of coalification: International Journal of Coal Geology, v. 20, p. 225-242.Kortenski, J., and I. Kostova, 1996, Occurrence and morphology of pyrite in Bulgarian coals: International Journal of Coal Geology, v. 29, p. 273-290.Kortenski, J., and S. Bakardjiev, 1993, Rare earth and radioactive elements in some coals from the Sofia, Svorge and Pernik Basins, Bulgaria: International Journal of Coal Geology, v. 22, p. 237-246.Korth, J., A.C. Hutton, and J. Ellis, 1990, A comparison of microscale pyrolysis and organic petrography for the estimation of yield from oil shale: Organic Geochemistry, v. 15, p. 477-483.Kosanke, R.M., 1951, A type of boghead coal from Illinois: American Journal of Science, v. 249, p. 444-450.Kosanke, R.M., 1951, A type of boghead coal from Illinois: American Journal of Science, v. 249, p. 444-450.Kosanke, R.M., 1952, Petrographic and microchemical studies of coal: Nova Scotia Department of Mines, Second conference on the origin and constitution of coal, p. 248-271.Kosanke, R.M., 1955, Petrographic and microchemical studies of coal: Second Conference on the Origin and Constitution of Coal, Crystal Cliffs, Nova Scotia, p. 248-267.Kosanke, R.M., and J.A. Harrison, 1957, Microscopy of the resin rodlets of Illinois coal: Illinois State Geological Survey Circular 234, 14 p.Kosina, M., 1984, Possibilities of the utilization of micropetrographic parameters in the scientific classification of bituminous coals: International Journal of Coal Geology, v. 4, p. 263-280.Košina, M., 1988, Effects of the properties and composition of coal blends on coke mechanical properties: Fuel, v. 67, p. 431-436.Kosina, M., and J. Hrncir, 1983, The properties of macerals in Czechoslovak coals rich in inertinite: International Journal of Coal Geology, v. 3, p. 145-156.Košina, M., and P. Heppner, 1985, Macerals in bituminous coals and the coking process. 2. Coal mass properties and the coke mechanical properties: Fuel, v. 64, p. 53-58.

Koenig, R.A., and R.A. Schraufnagel, 1992, Application of the slug test in coalbed methane testing, in Coalbed methane: Society of Petroleum Engineers, Reprint Series 35, p. 79-89.

Kolker, A., and F.E. Huggins, 2007, Progressive oxidation of pyrite in five bituminous coal samples: an As XANES and 57Fe Mössbauer spectroscopic study: Applied Geochemistry, v. 22, p. 778-787.Kolker, A., and F.E. Huggins, 2007, Progressive oxidation of pyrite in five bituminous coal samples: an As XANES and 57Fe Mössbauer spectroscopic study: Applied Geochemistry, v. 22, p. 778-787.

Komorek, J., R. Morga, and M. Pozzi, 1997, Optical anisotropy of vitrinite in coal seams from the fold area in the Upper Silesian coal basin (Poland), in M. Podemski, S. Dybova-Jachowicz, K. Jaworowski, J. Jureczka, and R. Wagner, eds., Proceedings of the XIII International Congress on the Carboniferous and Permian: Warsaw, Polish Geological Institute, Prace, v. 157, pt. 2, p. 183-192.

Koperna, G.J., Jr., R. Rhudy, R. Trautz, R. Esposito, and J. Hill, 2011, The SECARB anthropogenic test: the first U.S. integrated CO2 capture, transportation and storage test: 28th Annual International Pittsburgh Coal Conference, 10 p. http://www.adv-res.com/pdf/Pitt_Coal_Conference_Paper_FINAL.pdf

Korchagina, Y.I. and N.B. Vassoevich, 1974, Identification of bituminoid genetic types, in B. Tissot and F. Bienner, eds., Advances in organic geochemistry 1973: Paris, Editions Technip, p. 523-529.

Kostelnik, J., 2010, Geochemistry of the Marcellus Shale—a primer on organic geochemistry: Pennsylvania Geology, v. 40, no. 1, p. 3-13. http://www.dcnr.state.pa.us/topogeo/pub/pageolmag/pdfs/v40n1.pdf

Kosters, E.C., G.L. Chmura, and A. Bailey, 1987, Sedimentary and botanical factors influencing peat accumulation in the Mississippi Delta: London, Journal of the Geological Society, v. 144, no. 3, p. 423-434.Kostova, I., and A. Zdravkov, 2007, Organic petrology, mineralogy and depositional environment of the Kipra lignite seam, Maritza-West Basin, Bulgaria: International Journal of Coal Geology, v. 71, p. 527-541.Kostova, I., and A. Zdravkov, 2007, Organic petrology, mineralogy and depositional environment of the Kipra lignite seam, Maritza-West Basin, Bulgaria: International Journal of Coal Geology, v. 71, p. 527-541.Kostova, I., C. Vassileva, S. Dai, J.C. Hower, and D. Apostolova, 2013, Influence of surface area properties on mercury capture behavior of coal fly ashes from some Bulgarian power plants: International Journal of Coal Geology, v. 116-117, p. 227-235.Kostova, I.J., J.C. Hower, M. Mastalerz, and S.V. Vassilev, 2011, Mercury capture by selected Bulgarian fly ashes: influence of coal rank and fly ash carbon pore structure on capture efficiency: Applied Geochemistry, v. 26, p. 18-27.Koszorek, A., M. Krzesińska, S. Pusz, B. Pilawa, and B. Kwiecińska, 2009, Relationship between the technical parameters of cokes produced from blends of three Polish coals of difference coking ability: International Journal of Coal Geology, v. 77, p. 363-371.Kotarba, M.J., 2001, Composition and origin of coalbed gases in the upper Silesian and Lublin basins, Poland: Organic Geochemistry, v. 32, p. 163-180.Kotarba, M.J., and D.D. Rice, 2001, Composition and origin of coalbed gases in the lower Silesian basin, southwest Poland: Applied Geochemistry, v. 16, p. 895-910.Kotarba, M.J., and J.D. Lewan, 2004, Characterizing thermogenic coalbed gas from Polish coals of different ranks by hydrous pyrolysis: Organic Geochemistry, v. 35, p. 615-646.Kotter, K., 1960, Die mikroskopische reflexionsmessung mit dem photomultiplier und ihre anwendung auf die kohlenuntersuchung: Brennst .- Chemie, v. 41, p. 263-272.Koukouzas, N., C.R. Ward, and Z. Li, 2010, Mineralogy of lignites and associated strata in the Mavropigi field of the Ptolemais Basin, northern Greece: International Journal of Coal Geology, v. 81, p. 182-190.Kouwenberg, L.L.R., R.R. Hines, and J.C. McElwain, 2006, A new transfer technique to extract and process thin and fragmented fossil cuticle using polyester overlays: Review of Palaeobotany and Palynology, v. 145, p. 243-248.Koval, E., and J. Pope, 2006, Seeing a reservoir’s character from solution gas: World Oil, v. 227, no. 11, p. 144, 146.

Kremp, G.O., R.C. Neavel, and J.S. Starbuck, 1956, Coal types—a function of swamp environments: Nova Scotia Department of Mines, Third conference on the origin and constitution of coal, p. 270-286.Kretchman, H.F., 1957, The story of gilsonite: Salt Lake City, Utah, American Gilsonite Company, 96 p.Krickovic, S., and C. Findlay, 1971, Methane emission rate studies in a central Pennsylvania mine: U.S. Bureau of Mines, report of Investigations 7591, 9 p.Krishnaswamy, S., R.D. Gunn, and P.K. Agarwal, 1996, Low-temperature oxidation of coal. 2. An experimental and modeling investigation using a fixed-bed isothermal flow reactor: Fuel, v. 75, p. 344-352.Kristiansen, A., 1996, Understanding coal gasification: London, IEA Coal Research, IEA Coal Research Report Series, IEACR/86, 69 p.Krooss, B.M., F. van Bergen, Y. Gensterblum, N. Siemons, H.J.M. Pagnier, and P. David, 2002, High-pressure methane and carbon dioxide adsorption on dry and moisture-equilibrated Pennsylvanian coals: International Journal of Coal Geology, v. 51, p. 69-92.Krooss, B.M., F. van Bergen, Y. Gensterblum, N. Siemons, H.J.M. Pagnier, and P. David, 2002, High-pressure methane and carbon dioxide adsorption on dry and moisture-equilibrated Pennsylvanian coals: International Journal of Coal Geology, v. 51, p. 69-92.Kruge, M.A., B.A. Stankiewicz, J.C. Crelling, A. Montanari, and D.F. Bensley, 1994, Fossil charcoal in Cretaceous-Tertiary boundary strata: evidence for catastrophic firestorm and megawave: Geochimica et Cosmochimica Acta, v. 58, p. 1393-1397.Kruge, M.A., J.C. Crelling, E.J. Hippo, and S.R. Palmer, 1991, Aspects of sporinite chemistry: Organic Geochemistry, v. 17, p. 193-204.

Kruszewska, K., 1989, The use of reflectance to determine maceral composition and the reactive inert ratio of coal components: Fuel, v. 68, p. 753-757.Kruszewska, K., 1989, The use of reflectance to determine maceral composition and the reactive-inert ratio of coal components: Fuel, v. 68, p. 753-757.

Kruszewska, K.J., 2003, Fluorescing macerals in South African coals: International Journal of Coal Geology, v. 54, p. 79-94.Kruszewska, K.J., and V.M. Du Cann, 1996, Detection of the incipient oxidation of coal by petrographic techniques: Fuel, v. 75, p. 769-774.Kruszewski, Ł., 2013, Supergene sulphate minerals from the burning coal mining dumps in the Upper Silesian coal basin, south Poland: International Journal of Coal Geology, v. 105, p. 91-109.Krzesińska, M., S. Pusz, and Ł. Smędowski, 2009, Characterization of the porous structure of cokes produced from the blends of three Polish bituminous coking coals: International Journal of Coal Geology, v. 78, p. 169-176.Krzesińska, M., U. Szeluga, Ł. Smędowski, J. Majewska, S. Pusz, S. Czajkowska, and B. Kwiecińska, 2010, TGA and DMA studies of blends from very good coking Zofiówka coal and various carbon additives: weakly coking coals, industrial coke and carbonized plants: International Journal of Coal Geology, v. 81, p. 293-300.Krzesińska, M., U. Szeluga, S. Czajkowska, J. Muszyńska, J. Zachariasz, S. Pusz, B. Kwiecińska, A. Koszorek, and B. Pilawa, 2009, The thermal decomposition studies of three Polish bituminous coking coals and their blends: International Journal of Coal Geology, v. 77, p. 350-355.Kuangzong, Q., Y. Qiushui, G. Shaohui, L. Qinghua, and S. Wei, 1994, Chemical structure and hydrocarbon formation of the Huanxian brown coal, China: Organic Geochemistry, v. 21, p. 333-341.Kuchta, J.M., V.R. Rowe, and D.S. Burgess, 1980, Spontaneous combustion susceptibility in U.S. coals: U.S. Bureau of Mines, Report of Investigations 8474, 37 p.Kuehn, D.W., R.W. Snyder, and P.C. Painter, 1982, Characterization of vitrinite concentrates. 1. Fourier Transform infrared studies: Fuel, v. 61, p. 682-694.Kuehn, K.W., W.G. Lloyd, J.T. Riley, and D.W. Kuehn, 1988, Preparation and characterization of coal composition/particle size relations: Organic Geochemistry, v. 12, p. 413-417.Kuellmer, F.J., F. Kimbler, and J. Nuter, 1983, Preliminary report on the diffuse reflectivity of some New Mexico coals: International Journal of Coal Geology, v. 2, p. 261-277.

Kozusníková, A., P. Martinec, J. Pesek, and P. Valterová, 2002, Coal clasts in the Carboniferous sediments of the Upper Silesian Basin, in L.V. Hills, C.M. Henderson, and E.W. Bamber, eds., Carboniferous and Permian of the World: XIV ICCP proceedings: Canadian Society of Petroleum Geologists Memoir 19, p. 895-901.Krejci-Graf, K., 1983, Minor elements in coals, in S.S. Augustithis, ed., The significance of trace elements in solving petrogenetic problems and controversies: Athens, Greece, Theophrastus Publications S.A., p. 533-597.

Kruge, M.A., J.F. Hubert, D.F. Bensley, J.C. Crelling, R.J. Akes, and P.E. Meriney, 1990, Organic geochemistry of a Lower Jurassic synrift lacustrine sequence, Hartford basin, Connecticut, U.S.A., in B. Durand and F. Behar, eds., Advances in organic geochemistry 1989, part II, molecular geochemistry: Organic Geochemistry, v. 16, p. 689-701.

Kruszewska, K., 1997, A new method of measurements of vitrinite reflectance and maceral content, in M. Podemski, S. Dybova-Jachowicz, K. Jaworowski, J. Jureczka, and R. Wagner, eds., Proceedings of the XIII International Congress on the Carboniferous and Permian: Warsaw, Polish Geological Institute, Prace, v. 157, pt. 2, p. 233-238.Kruszewska, K., 1997, A new method of measurements of vitrinite reflectance and maceral content, in M. Podemski, S. Dybova-Jachowicz, K. Jaworowski, J. Jureczka, and R. Wagner, eds., Proceedings of the XIII International Congress on the Carboniferous and Permian: Warsaw, Polish Geological Institute, Prace, v. 157, pt. 2, p. 233-238.Kruszewska, K., 1997, Behaviour of pseudovitrinite under heating conditions, in M. Podemski, S. Dybova-Jachowicz, K. Jaworowski, J. Jureczka, and R. Wagner, eds., Proceedings of the XIII International Congress on the Carboniferous and Permian: Warsaw, Polish Geological Institute, Prace, v. 157, pt. 2, p. 239-242.

Kuenzer, C., J. Zhang, Y. Sun, Y. Jia, and S. Dech, 2012, Coal fires revisited: The Wuda coal field in the aftermath of extensive coal fire research and accelerating extinguishing activities: International Journal of Coal Geology, v. 102, p. 75-86.Kuhn, J.K., F.L. Fiene, R.A. Cahill, H.J. Gluskoter, and N.F. Shimp, 1980, Abundance of trace and minor elements in organic and mineral fractions of coal: Illinois State Geological Survey, Environmental Geology Notes 88, 67 p.Kuili, J., X. Jian, and H. Duohu, 1988, The use of automated coal petrography in determining maceral group composition and the reflectance of vitrinite: International Journal of Coal Geology, v. 9, p. 385-395.

Kulander, B.R., and S.L. Dean, 1993, Coal-cleat domains and domain boundaries in the Allegheny Plateau of West Virginia: AAPG Bulletin, v. 77, p. 1374-1388.Kulkarni, P., 2010, From shale gas to shale oil to oil shale: World Oil, v. 231, no. 8, p. 19.Kumar, H., D. Elsworth, J.P. Mathews, J. Liu, and D. Pone, 2014, Effect of CO2 injection on heterogeneously permeable coalbed reservoirs: Fuel, v. 135, p. 509-521.Kumar, H., D. Elsworth, J.P. Mathews, J. Liu, and D. Pone, 2014, Effect of CO2 injection on heterogeneously permeable coalbed reservoirs: Fuel, v. 135, p. 509-521.Kumar, H., E. Lester, S. Kingman, R. Bourne, C. Avila, A. Jones, J. Robinson, P.M. Halleck, and J.P. Mathews, 2011, Inducing fractures and increasing cleat apertures in a bituminous coal under isotropic stress via application of microwave energy: International Journal of Coal Geology, v. 88, p. 75-82.Kumar, R., V. Bansal, R.M. Badhe, I.S.S. Madhira, V. Sugumaran, S. Ahmed, J. Christopher, M.B. Patel, and B. Basu, 2013, Characterization of Indian origin oil shale using advanced analytical techniques: Fuel, v. 113, p. 610-616.Kurylowicz, L.E., S. Ozimic, D.M. McKirdy, A.J. Kantsler, and A.C. Cook, 1976, Reservoir and source rock potential of the Larapinta Group, Amadeus basin, central Australia: APEA Journal, v. 16, part 1, p. 49-65.Kutchko, B.G., A.L. Goodman, E. Rosenbaum, S. Natesakhawat, and K. Wagner, 2013, Characterization of coal before and after supercritical CO2 exposure via feature relocation using field-emission scanning electron microscopy: Fuel, v. 107, p. 777-786.Kuuskraa, V., and M. Godec, 2009, Turning lemons into lemonade: Achieving benefits from CCS: Hart’s E&P, v. 82, no. 11, p. 74-76. (CO2-EOR)

Kwiecinska, B., and H.I. Petersen, 2004, Graphite, semi-graphite, natural coke, and natural char classification—ICCP system: International Journal of Coal Geology, v. 57, p. 99-116.Kwiecinska, B., and H.I. Petersen, 2004, Graphite, semi-graphite, natural coke, and natural char classification—ICCP system: International Journal of Coal Geology, v. 57, p. 99-116.Kwiecińska, B., and H.I. Petersen, 2004, Graphite, semi-graphite, natural coke, and natural char classification—ICCP system: International Journal of Coal Geology, v. 57, p. 99-116.Kwiecińska, B., and H.I. Petersen, 2004, Graphite, semi-graphite, natural coke, and natural char classification—ICCP system: International Journal of Coal Geology, v. 57, p. 99-116.Kwiecińska, B., and H.I. Petersen, 2004, Graphite, semi-graphite, natural coke, and natural char classification—ICCP system: International Journal of Coal Geology, v. 57, p. 99-116.Kwiecinska, B., D.G. Murchison, and E. Scott, 1977, Optical properties of graphite: Journal of Microscopy, v. 104, no. 3, p. 294-302.Kwiecinska, B., S. Pusz, M. Krzesinska, and B. Pilawa, 2007, Physical properties of shungite: International Journal of Coal Geology, v. 71, p. 455-461.La Pointe, P., and R. Ord, 2007, Find EOR, carbon-capture tradeoffs: Hart’s E&P, v. 80, no. 6, p. 87-88.Laban, K.L., and B.P. Atkin, 1999, The determination of minor and trace element associations in coal using a sequential microwave digestion procedure: International Journal of Coal Geology, v. 41, p. 351-369.

Ladoo, R.B., 1920, The natural hydrocarbons; gilsonite, elaterite, wurtzilite, grahamite, ozokerite and others: U.S. Bureau of Mines Report of Investigations 2121, 12 p.Lafargue, E., F. Marquis, and D. Pillot, 1998, Rock-Eval 6 applications in hydrocarbon exploration, production, and soil contamination studies: Oil & Gas Science and Technology – Rev. IFP 53, p. 421-437.Lahann, R., M. Mastalerz, J.A. Rupp, and A. Drobniak, 2013, Influence of CO2 on New Albany Shale composition and pore structure: International Journal of Coal Geology, v. 108, p. 2-9.Lahann, R., M. Mastalerz, J.A. Rupp, and A. Drobniak, 2013, Influence of CO2 on New Albany Shale composition and pore structure: International Journal of Coal Geology, v. 108, p. 2-9.

Lama, R.D., and J. Bodziony, 1998, Management of outburst in underground coal mines: International Journal of Coal Geology, v. 35, p. 83-115.

Lamarre, R.A., 2003, Hydrodynamic and stratigraphic controls for a large coalbed methane accumulation in Ferron coals of east-central Utah: International Journal of Coal Geology, v. 56, p. 97-110.Lamarre, R.A., 2006, Coalbed methane production from Ferron coals in east-central Utah: The Mountain Geologist, v. 43, no. 3, p. 207-211.Lamarre, R.A., and T.J. Pratt, 2002, Reservoir characterization study: calculation of gas-in-place in Ferron coals at Drunkard’s Wash Unit, Carbon and Emergy Counties, Utah: The Mountain Geologist, v. 39, p. 41-51.Lamarre, R.A., compiler, 2006, Coalbed methane: A compendium of influential papers: AAPG Datapages Getting Started No. 3, CD.Lamberson, M.N., and R.M. Bustin, 1993, Coalbed methane characteristics of Gates Formation coals, northeastern British Columbia: effect of maceral composition: AAPG Bulletin, v. 77, p. 2062-2076.Lamberson, M.N., R.M. Bustin, and W. Kalkreuth, 1991, Lithotype (maceral) composition and variation as correlated with paleo-wetland environments, Gates Formation, northeastern British Columbia, Canada: International Journal of Coal Geology, v. 18, p. 87-124.Lamberson, M.N., R.M. Bustin, and W. Kalkreuth, 1991, Lithotype (maceral) composition and variation as correlated with paleo-wetland environments, Gates Formation, northeastern British Columbia, Canada: International Journal of Coal Geology, v. 18, p. 87-124.Lamberson, M.N., R.M. Bustin, W.D. Kalkreuth, and K.C. Pratt, 1996, The formation of inertinite-rich peats in the mid-Cretaceous Gates Formation: implications for the interpretation of mid-Albian history of paleowildfire: Palaeogeography, Palaeoclimatology, Palaeoecology, v. 120, p. 235-260.

Kuili, J., Y. Supig, W. Hui, and H. Duohu, 1999, Jurassic coals and carbonaleans mudstones: the oil source in the Junggar and Turpan-Hami basins, China, in M. Mastalerz, M. Glikson, and S.D. Golding, eds., Coalbed methane: scientific, environmental and economic evaluation: Boston, Kluwer Academic Publishers, p. 545-553.

Kuuskraa, V.A., and C.M. Boyer, II, 1993, Economic and parametric analysis of coalbed methane, in B.E. Law and D.D. Rice, eds., Hydrocarbons from coal: AAPG Studies in Geology 38, p. 373-394.Kvale, E.P., D.W. Engelhardt, M. Mastalerz, C.B. Rexroad, L.C. Furer, and C.F. Eble, 2004, Atokan and early Desmoinesian coal-bearing parasequences in Indiana, U.S.A., in J.C. Pashin and R.A. Gastaldo, eds., Sequence stratigraphy, paleoclimate, and tectonics of coal-bearing strata: AAPG Studies in Geology 51, p. 71-88. in J.C. Pashin and R.A. Gastaldo, eds., Sequence stratigraphy, paleoclimate, and tectonics of coal-bearing strata: AAPG Studies in Geology 51, p.

Laczo, I., and A. Jambor, 1988, Secondary heating of vitrinite: some geological implications, in L.H. Royden and F. Horvath, eds., The Pannonian basin, a study in basin evolution: AAPG Memoir 45, p. 311-318.

Lallier-Verges, E., P. Bertrand, J.-M. Guet, C. Clinard, Q. Lin, and X.-Q. Wu, 1991, Ultrafine structures of vitrinites: an electron microscopy study of microlithotypes in humic coals, in P. Bertrand, ed., Coal: formation, occurrence and related properties: Bulletin de la Societe Geologique de France, v. 162, p. 163-174.

Lamarre, R. A., and T. D. Burns, 1997, Drunkard's Wash Unit: Coalbed methane production from Ferron Coals in east-central Utah, in E. B. Coalson, J. C. Osmond and E. T. Williams, eds., Innovative applications of petroleum technology in the Rocky Mountain area: RMAG, p.47-60.Lamarre, R.A., 2002, Hydrodynamic and stratigraphic controls for a large coalbed methane accumulation in Ferron coals of east-central Utah, in S.D. Schwochow and V.F. Nuccio, eds., Coalbed methane of North America, II: Rocky Mountain Association of Geologists, p. 71-82.

Lamberson, M.N., R.M. Bustin, W.D. Kalkreuth, and K.C. Pratt, 1996, The formation of inertinite-rich peats in the mid-Cretaceous Gates Formation: implications for the interpretation of mid-Albian history of paleowildfires: Palaeogeography, Palaeoclimatology, Palaeoecology, v. 120, p. 235-260.Lambert, D.E., C.J.R. Fookes, and J.D. Saxby, 1988, N.m.r. analysis of shale oils from fresh and artificially weathered oil shales: Fuel, v. 67, p. 1386-1390.Lambert, S.W., and T.E. Lombardi, 2002, Illinois basin coal gas, unlocking a new frontier using old keys (abstract): AAPG Annual Convention Official Program, v. 11, p. A98.

Landais, P., 1995, Statistical determination of geochemical parameters of coal and kerogen macerals from transmission micro-infrared spectroscopy data: Organic Geochemistry, v. 23, p. 711-720. (FTIR)Landais, P., and A. Rochdi, 1993, In situ examination of coal macerals oxidation by micro-FT-i.r. spectroscopy: Fuel, v. 72, p. 1393-1401.Landais, P., M. Monthious, and J.D. Meunier, 1984, Importance of the oxidation/maturation pair in the evolution of humic coals: Organic Geochemistry, v. 7, p. 249-260.Landais, P., M. Monthioux, and J.-D. Meunier, 1984, Importance of the oxidation/maturation pair in the evolution of humic coals: Organic Geochemistry, v. 7, p. 249-260.Landais, P., R. Michels, and M. Elie, 1994, Are time and temperature the only constraints to the simulation of organic matter maturation?: Organic Geochemistry, v. 22, p. 617-630.Landais, P., R. Michels, J. Kister, J.-M. Dereppe, and Z. Benhedda, 1991, Behavior of oxidized type II kerogen during artificial maturation: Energy Fuels, v. 5, p. 860-866.Landheer, F., H. Dibbs, and J. Labuda, 1982, Trace elements in Canadian coals: Ottawa, Ontario, Environment Canada, Environmental Protection Report 3-AP-82-6, 41p.Landis, C.R., and J.R. Castaño, 1994, Maturation and bulk chemical properties of a suite of solid hydrocarbons: Organic Geochemistry, v. 22, p. 137-149.Landis, C.R., and J.R. Castaño, 1994, Maturation and bulk chemical properties of a suite of solid hydrocarbons: Organic Geochemistry, v. 22, p. 137-149.Landis, C.R., and J.T. Senftle, 1990, Thoughts concerning the role of fluorescence spectroscopy in organic petrology: TSOP Newsletter, v. 7, no. 2, p. 7.Landis, C.R., J.C. Crelling, G.W. Sullivan, M.W. Pleil, and W.L. Borst, 1987, Results of laser-induced fluorescence of organic materials: Organic Geochemistry, v. 11, p. 423.Landis, C.R., S. Gangopadhyay, and W.L. Borst, 1991, Photochemistry of an unusual exsudatinite in Permian Basin shales: Chemical Geology, v. 93, p. 111-128.Landis, E.R., T.J. Rohrbacher, C.E. Barker, B. Fodor, and G. Gombar, 2003, Coalbed gas in the Mecsek Basin, Hungary: International Journal of Coal Geology, v. 54, p. 41-55.Lang, L., and Z. Fu-bao, 2010, A comprehensive hazard evaluation system for spontaneous combustion of coal in underground mining: International Journal of Coal Geology, v. 82, p. 27-36.Langenberg, C.W., A. Beaton, and H. Berhane, 2006, Regional evaluation of the coalbed-methane potential of the Foothills/Mountains of Alberta, Canada: International Journal of Coal Geology, v. 65, p. 114-128.

Langenberg, W., A. Beaton, and M. Berhane, 2002, Regional evaluation of the CBM potential of the foothills/mountains of Alberta, Canada (abstract): AAPG Annual Convention Official Program, v. 11, p. A99.Langenberg, W., and W. Kalkreuth, 1991, Reflectance anisotropy and syn-deformational coalification of the Jewel seam in the Cadomin area, Alberta, Canada: International Journal of Coal Geology, v. 19, p. 303-317.Langenberg, W., W. Kalkreuth, J. Levine, R. Strobl, T. Demchuk, G. Hoffman, and T. Jerzykiewicz, 1990, Coal geology and its application to coal-bed methane reservoirs, lecture notes for short course: Alberta Research Council Information Series 109, 159 p.Langenberg, W., W. Kalkreuth, J. Levine, R. Strobl, T. Demchuk, G. Hoffman, and T. Jerzykiewicz, 1990, Coal geology and its application to coal-bed methane reservoirs: Alberta Research Council Information Series 109, 159 p.Langenheim, J.H., 1969, Amber: a botanical inquiry: Science, v. 163, no. 3872, p. 1157-1169.Langenheim, J.H., 1969, Amber: a botanical inquiry: Science, v. 163, no. 3872, p. 1157-1169.Langenheim, J.H., 1990, Plant resins: American Scientist, v. 78, p. 16-24.

Langenheim, J.H., 2003, Plant resins: Chemistry, evolution, ecology, ethnobotany: Portland, OR, Timber Press, 586 p.

Langford, F.F., and M.-M. Blanc-Valleron, 1990, Interpreting Rock-Eval pyrolysis data using graphs of pyrolizable hydrocarbons vs. total organic carbon: AAPG Bulletin, v. 74, p. 799-804.Langhus, B.G., D. Arthur, J. Halvorson, and T. Richmond, 2002, Managing coal bed methane produced waters to minimize present costs and environmental liabilities (abstract): AAPG Annual Convention Official Program, v. 11, p. A99.Langhus, B.G., D. Arthur, J. Halvorson, and T. Richmond, 2002, Managing coal bed methane produced waters to minimize present costs and environmental liabilities (abstract): AAPG Annual Convention Official Program, v. 11, p. A99.Langrock, U., and R. Stein, 2004, Origin of marine petroleum source rocks from the Late Jurassic to Early Cretaceous Norwegian Greenland seaway—evidence for stagnation and upwelling: Marine and Petroleum Geology, v. 21, p. 157-176.Lapo, A.V., 1978, Comparative characteristics of vitrinites of Carboniferous coals of the Ukraine and Jurassic coals of Siberia: Fuel, v. 57, p. 179-183.

Largeau, C., S. Derenne, F. Le Berre, and J. Connan, 1994, Non-hydrolysable macromolecules of bacterial cell walls. Role in kerogen formation. Petrographic and chemical features of derived kerogens: Bulletin Des Centres De Recherches Exploration-Production, v. 18, Special Publication, p. 283-285.Larsen, J.W., 2004, The effects of dissolved CO2 on coal structure and properties: International Journal of Coal Geology, v. 57, p. 63-70.Larsen, J.W., 2004, The effects of dissolved CO2 on coal structure and properties: International Journal of Coal Geology, v. 57, p. 63-70.Larsen, J.W., ed., 1978, Organic chemistry of coal: American Chemical Society, ACS Symposium Series 71, 327 p.Larter, S., 1989, Chemical models of vitrinite reflectance evolution: Geologische Rundschau, v. 78, p. 349-359.

Lampe, C., and L. Schwark, 2012, Using geochemical analysis to identify a spatial maturity anomaly—An example from the Upper Rhine Graben, Germany, in N.B. Harris and K.E. Peters, eds., Analyzing the thermal history of sedimentary basins: Methods and case studies: SEPM Special Publication 103, p. 187-198. (enhanced convective hydrothermal heat flow)

Langenberg, W., 1991, Coalification patterns and coalbed methane potential in the Cadomin area, Alberta, Canada, in R.B. Finkelman and D. C. Peters, eds., Practical applications of coal geology: Journal of Coal Quality, v. 10, p. 89-95.

Langenheim, J.H., 1995, Biology of amber-producing trees: focus on case studies of Hymenaea and Agathis, in K.B. Anderson and J.C. Crelling, eds., Amber, resinite, and fossil resins: Washington, D.C., American Chemical Society Symposium Series 617, p. 1-31.

Langenheim, R.L., Jr., and W.J. Nelson, 1992, The cyclothemic concept in the Illinois Basin: a review, in R.H. Dott, ed., Eustasy: the historical ups and downs of a major geological concept: Geological Society of America Memoir 180, p. 55-71.

Largeau, C., S. Derenne, E. Casadevall, C. Berkaloff, M. Corolleur, B. Lugardon, J.F. Raynaud, and J. Connan, 1990, Occurrence and origin of "ultralaminar" structures in "amorphous" kerogens of various source rocks and oil shales, in B. Durand and F. Behar, eds., Advances in organic geochemistry 1989, part II, molecular geochemistry: Organic Geochemistry, v. 16, p. 889-895.

Larue, D.K., 1991, Organic matter in the Franciscan and Cedros subduction complexes: the problems of ‘instantaneous maturation’ and ‘missing petroleum’ in accretionary prisms: Marine and Petroleum Geology, v. 8, p. 468-482.Lash, G.G., 2006, Vitrinite suppression in Devonian black shale, western New York state: preliminary results (abstract): AAPG Eastern Section meeting, Buffalo, N.Y.Laubach, S.E., and C.M. Tremain, 1994, Fracture swarms: potential targets for methane exploration in Upper Cretaceous sandstone and coal, northern San Juan basin: New Mexico Bureau of Mines and Mineral Resources, Bulletin 146, p. 9-12.

Law, B.E., 1993, The relationship between coal rank and cleat spacing: implications for the prediction of permeability in coal: Proceedings of the 1993 International CBM Symposium, paper 9341, p. 435-442.

Law, B.E., and D.D. Rice, eds., 1993, Hydrocarbons from coal: AAPG Studies in Geology 38, 400 p.Law, B.E., and D.D. Rice, eds., 1993, Hydrocarbons from coal: AAPG Studies in Geology 38, 400 p.

Law, B.E., V.F. Nuccio, and C.E. Barker, 1989, Kinky vitrinite reflectance profiles -- evidence of paleopore pressure in low-permeability gas-bearing sequences in Rocky Mountain foreland basins: AAPG Bulletin, v. 73, p. 999-1010.Lawrence, A.W., 1993, Coalbed methane produced-water treatment and disposal options: Quarterly Review of Methane from Coal Seams Technology, v. 11, no. 2, p. 6-17.Lawrence, A.W., 1993, Coalbed methane produced-water treatment and disposal options: Quarterly Review of Methane from Coal Seams Technology, v. 11, no. 2, p. 6-17.Lawson, B., 2011, CO2 availability key to the future of CO2 EOR in U.S.: American Oil & Gas Reporter, v. 54, no. 10, p. 31.Lawson, B., 2012, There is progress on capturing CO2 to use in enhanced recovery: American Oil & Gas Reporter, v. 55, no. 2, p. 27.Laxminarayana, C., and P.J. Crosdale, 1999, Role of coal type and rank on methane sorption characteristics of Bowen basin, Australia coals: International Journal of Coal Geology, v. 40, p. 309-325.Laxminarayana, C., and P.J. Crosdale, 2001, Heat of methane adsorption of coal: implications for pore structure development: Tuscaloosa, Alabama, Proceedings, International Coalbed Methane Symposium, Paper 114, p. 151-162.Laxminarayana, C., and P.J. Crosdale, 2002, Controls on methane sorption capacity of Indian coals: AAPG Bulletin, v. 86, p. 201-212.Le Bayon, R., C. Adam, and R.F. Mählmann, 2012, Experimentally determined pressure effect on vitrinite reflectance at 450°C: International Journal of Coal Geology, v. 92, p. 69-81.Le Bayon, R., G.P. Brey, W.G. Ernst, and R. Ferreiro Mählmann, 2011, Experimental kinetic study of organic matter maturation: Time and pressure effects on vitrinite reflectance at 400 ºC: Organic Geochemistry, v. 42, p. 340-355.Le Bayon, R., G.P. Brey, W.G. Ernst, and R. Ferreiro Mählmann, 2011, Experimental kinetic study of organic matter maturation: Time and pressure effects on vitrinite reflectance at 400 ºC: Organic Geochemistry, v. 42, p. 340-355.Le Bayon, R., S. Buhre, B.C. Schmidt, and R.F. Mählmann, 2012, Experimental organic matter maturation at 2 kbar: Heat-up effect to low temperatures on vitrinite reflectance: International Journal of Coal Geology, v. 92, p. 45-53.Leach, W.H., Jr., 2003, Enhanced oil recovery, CO2 flooding: Oil and Gas Investor, v. 23, no. 11, p. 57-59.Leblond, D., 2005, IEA: CO2 capture, storage offer emissions solution: Oil & Gas Journal, v. 103.2, p. 29-30.

Lee, G.K., and H. Whaley, 1983, Modification of combustion and fly-ash characteristics by coal blending: Journal of the Institute of Energy, v. 56, p. 190-197.Lee, H.W., 1964, A modified method of coal maceration and a simple technique for slide preparation: Micropaleontology, v. 10, p. 486-490.Lee, J.A., B.S.M. Faraj, B.W. McKinstry, and G.R. Sloan, 2004, Program planning and field operations protocols for coalbed methane and shale gas reservoirs in Canada: GasTIPS, v. 10, no. 4, p. 18-21.Lee, Y., and D. Deming, 2002, Overpressures in the Anadarko basin, southwestern Oklahoma: static or dynamic?: AAPG Bulletin, v. 86, p. 145-160.(also in OGS Circular 106, p. 133-150.)Legall, F.D., C.R. Barnes, and R.W. MacQueen, 1981, Thermal maturation, burial history and hotspot development of Paleozoic strata of southern Ontario – Quebec, from conodont and acritarch colour alteration studies: Bulletin of Canadian Petroleum Geology, v. 29, p. 492-539. (proposed acritarch alteration index, AAI)

Lemons, B.N., and L. Nemirow, 1989, Maximizing the Section 29 credit in coal seam methane transactions: Journal of Taxation, v. 70, p. 238-245.Lemos de Sousa, M.J., and H.J. Pinheiro, 1994, Coal classification: basic fundamental concepts and the state of the existing international systems: Journal of Coal Quality, v. 13, p. 52-66.

Lester, E., D. Alvarez, A.G. Borrego, B. Valentim, D. Flores, D.A. Clift, P. Rosenberg, B. Kwiecinska, R. Barranco, H.I. Petersen, M. Mastalerz, K.S. Milenkova, C. Panaitescu, M.M. Marques, A. Thompson, D. Watts, S. Hanson, G. Predeanu, M. Misz, and T. Wu, 2010, The procedure used to develop a coal char classification—Commission III Combustion Working Group of the International Committee for Coal and Organic Petrology: International Journal of Coal Geology, v. 81, p. 333-342.Lester, E., D. Watts, and M. Cloke, 2002, A novel automated image analysis method for maceral analysis: Fuel, v. 81, p. 2209-2217.

Lett, R.G., and T.C. Ruppel, 2004, Coal, chemical and physical properties: Boston, Elsevier Academic Press, Encyclopedia of Energy, vol. 1, p. 411-423.

Larter, S.R., 1985, Integrated kerogen typing in the recognition and quantitative assessment of petroleum source rocks, in B.M. Thomas, et al., eds., Petroleum geochemistry in exploration of the Norwegian Shelf: London, Graham & Trotman, p. 269-286.

Laubach, S.E., C.M. Tremain, and W.B. Ayers, Jr., 1991, Coal fracture studies: guides for coalbed methane exploration and development, in R.B. Finkelman and D.C. Peters, eds., Practical applications of coal geology: Journal of Coal Quality, v. 10, p. 81-88.Laubach, S.E., R.A. Marrett, J.E. Olson, and A.R. Scott, 1998, Characteristics and origins of coal cleat: a review, in R.M. Flores, ed., Coalbed methane: from coal-mine outbursts to a gas resource: International Journal of Coal Geology, v. 35, p. 175-207.Law, B.E., 1988, Coal-bed methane, in L.B. Magoon, ed., Petroleum systems of the United States: USGS Bulletin 1870, p. 52-53.Law, B.E., 1992, Coalbed methane, in L.B. Magoon, ed., The petroleum system -- status of research and methods, 1992: U.S. Geological Survey Bulletin 2007, p. 20-21.

Law, B.E., and D.D. Rice, 1993, Coalbed methane - new perspectives on an old source of energy, in S.-H. Chiang, ed., Coal - energy and the environment: Tenth Annual International Pittsburgh Coal Conference, Proceedings, p. 316-319.

Law, B.E., D.D. Rice, and R.M. Flores, 1991, Coalbed gas accumulations in the Paleocene Fort Union Formation, Powder River Basin, Wyoming, in S.D. Schwochow, D.K. Murray, and M.F. Fahy, eds., Coalbed methane of western North America: Denver, CO, Rocky Mountain Association of Geologists Guidebook, p. 179-190.

Lee, E.S., 1979, Coal liquefaction, in C.Y. Wen and E.S. Lee, eds., Coal conversion technology: Reading, MA, Addison-Wesley Publishing Co., p. 428-545.

Lehtonen, K., and M. Ketola, 1993, Solvent-extractable lipids of Sphagnum, Carex, Bryales and Carex-Bryales peats: content and compositional features vs peat humification: Organic Geochemistry, v. 20, p. 363-380.

Leonard, J.W., and B.A. Donahue, 1976, Agglomerating properties as measured by coal petrography applied through conventional test procedures, in C.J. Smith, compiler, Proceedings of the coal agglomeration and conversion symposium: West Virginia Geological and Economic Survey, p. 85-111.

Lester, E., M. Allen, M. Cloke, and B. Atkin, 1996, Analysis of the problems associated with the use of image analysis for microlithotype analysis on solid coal mounts, in R. Gayer and I. Harris, eds., Coalbed methane and coal geology: London, Geological Society Special Publication 109, p. 237-248.

Levandowski, J., and W. Kalkreuth, 2009, Chemical and petrographical characterization of feed coal, fly ash and bottom ash from the Figueira power plant, Paraná, Brazil: International Journal of Coal Geology, v. 77, p. 269-281.Levine, J.R., 1986, Deep burial of coal-bearing strata, Anthracite region, Pennsylvania: sedimentation or tectonics?: Geology, v. 14, p. 577-580.Levine, J.R., 1987, Characteristics and origin of fracture-hosted impsonite, Quebec City area, Canada: Organic Geochemistry, v. 11, p. 425-426.Levine, J.R., 1987, Influence of coal composition on the generation and retention of coalbed natural gas: Tuscaloosa, Alabama, Proceedings of the 1987 Coalbed Methane Symposium, paper 8711, p. 15-18.

Levine, J.R., 1991, New methods for assessing gas resources in thin-bedded, high-ash coals: Tuscaloosa, Alabama, Proceedings of the 1991 Coalbed Methane Symposium, paper 9125, p. 115-125.Levine, J.R., 1991, The impact of oil formed during coalification on generation and storage of natural gas in coalbed reservoir systems: Tuscaloosa, Alabama, Proceedings of the 1991 Coalbed Methane Symposium, paper 9126, p. 307-315.Levine, J.R., 1992, Five common misconceptions regarding coalbed gas reservoir systems: Quarterly Review of Methane from Coal Seams Technology, v. 9, nos. 3-4, p. 36.Levine, J.R., 1992, Oversimplifications can lead to faulty coalbed gas reservoir analysis: Oil & Gas Journal, v. 90, no. 47, p. 63-69.

Levine, J.R., and A. Davis, 1984, Optical anisotropy of coals as an indicator of tectonic deformation, Broad Top coal field, Pennsylvania: GSA Bulletin, v. 95, p. 100-108.Levine, J.R., and A. Davis, 1989, Reflectance anisotropy of Upper Carboniferous coals in the Appalachian foreland basin, Pennsylvania, U.S.A.: International Journal of Coal Geology, v. 13, p. 341-373.Levine, J.R., and A. Davis, 1989, The relationship of coal optical fabrics to Alleghanian tectonic deformation in the central Appalachian fold-and-thrust belt, Pennsylvania, U.S.A.: GSA Bulletin, v. 101, p. 1333-1347.Levine, J.R., and A. Davis, 1989, The relationship of coal optical fabrics to Alleghanian tectonic deformation in the central Appalachian fold-and-thrust belt, Pennsylvania: Geological Society of America Bulletin, v. 101, p. 1333-1347.Levine, J.R., and A. Davis, 1990, Reflectance anisotropy of Carboniferous coals in the Appalachian foreland basin, Pennsylvania, U.S.A.: International Journal of Coal Geology, v. 16, p. 201-204.Levine, J.R., and T. Yalan, 1989, Secondary porosity in coal and its relationship to coal metamorphism: Proceedings, Coal: formation, occurrence, and related properties: Orleans, France, Paper 42.Levine, J.R., I.M. Samson, and R. Hesse, 1991, Occurrence of fracture-hosted impsonite and petroleum fluid inclusions, Quebec City region, Canada: AAPG Bulletin, v. 75, p. 139-155.Levy, J.H., S.J. Day, and J.S. Killingley, 1997, Methane capacities of Bowen basin coals related to coal properties: Fuel, v. 76, p. 813-819.

Lewan, M.D., 1993, Identifying and understanding suppressed vitrinite reflectance through hydrous pyrolysis experiments (abstract): TSOP Abstracts and Program, v. 10, p. 1-3.Lewan, M.D., 1994, Effects of weathering on the reflectance of vitrinite in the Mowry Shale, Steinaker Reservoir, Utah (abstract): 1994 AAPG Annual Convention, Official Program, v. 3, p. 197.Lewan, M.D., and J.A. Williams, 1987, Evaluation of petroleum generation from resinites by hydrous pyrolysis: AAPG Bulletin, v. 71, p. 207-214.Lewińska-Preis, L., M.J. Fabiańska, S. Ćmiel, and A. Kita, 2009, Geochemical distribution of trace elements in Kaffioyra and Longyearbyen coals, Spitsbergen, Norway: International Journal of Coal Geology, v. 80, p. 211-223.Lewis, J.E., 2013, Evaluation of the Newburg Sandstone of the Appalachian Basin as a CO2 geologic storage resource: Environmental Geosciences Journal, v. 20, no. 4.Lewis, R.T., 1999, Coalbed methane production of the Buck Knob anticline field, Wise County, Virginia (abstract): AAPG Bulletin, v. 83, p. 1370.Lewis, S.E., and J.C. Hower, 1990, Implications of thermal events on thrust emplacement sequence in the Appalachian fold and thrust belt: some new vitrinite reflectance data: Journal of Geology, v. 98, p. 927-942.Leythaeuser, D., 1973, Effects of weathering on organic matter in shales: Geochimica et Cosmochimica Acta, v. 37, p. 113-120.Leythaeuser, D., A. Mackenzie, R.G. Schaefer, and M. Bjoroy, 1984, A novel approach for recognition and quantification of hydrocarbon migration effects in shale-sandstone sequences: AAPG Bulletin, v. 68, p. 196-219.

Li, D., P. Hendry, and M. Faiz, 2008, A survey of the microbial populations in some Australian coalbed methane reservoirs: International Journal of Coal Geology, v. 76, p. 14-24.Li, D., Q. Liu, P. Weniger, Y. Gensterblum, A. Busch, and B.M. Krooss, 2009, High-pressure sorption isotherms and sorption kinetics of CH4 and CO2 on coals: Fuel, v. 89, p. 569-580.Li, D., Q. Liu, P. Weniger, Y. Gensterblum, A. Busch, and B.M. Krooss, 2009, High-pressure sorption isotherms and sorption kinetics of CH4 and CO2 on coals: Fuel, v. 89, p. 569-580. (subbituminous coals have highest CO2 sorption capacity)Li, E., C. Pan, S. Yu, X. Jin, and J. Liu, 2013, Hydrocarbon generation from coal, extracted coal and bitumen rich coal in confined pyrolysis experiments: Organic Geochemistry, v. 64, p. 58-75.Li, J., D. Liu, Y. Yao, Y. Cai, and Y. Chen, 2013, Evaluation and modeling of gas permeability changes in anthracite coals: Fuel, v. 111, p. 606-612.Li, J., D. Liu, Y. Yao, Y. Cai, and Y. Qiu, 2011, Evaluation of the reservoir permeability of anthracite coals by geophysical logging data: International Journal of Coal Geology, v. 87, p. 121-127.Li, J., X. Zhuang, and X. Querol, 2011, Trace element affinities in two high-Ge coals from China: Fuel, v. 90, p. 240-247.Li, J., X. Zhuang, X. Querol, O. Font, M. Izquierdo, and Z. Wang, 2014, New data on mineralogy and geochemistry of high-Ge coals in the Yimin coalfield, Inner Mongolia, China: International Journal of Coal Geology, v. 125, p. 10-21.

Levine, J.R., 1990, Generation, storage and migration of natural gas in coal bed reservoirs, in W. Langenberg, W. Kalkreuth, J. Levine, R. Strobl, T. Demchuk, G. Hoffman, and T. Jerzykiewicz, Coal geology and its application to coal-bed methane reservoirs: Alberta Research Council, Information Series 109, p. 84-130.

Levine, J.R., 1993, Coalfication: the evolution of coal as source rock and reservoir rock for oil and gas, in B.E. Law and D.D. Rice, eds., Hydrocarbons from coal: AAPG Studies in Geology 38, p. 39-77 (Rock-Eval p. 59-60)Levine, J.R., 1993, Coalification: the evolution of coal as source rock and reservoir rock for oil and gas, in B.E. Law and D.D. Rice, eds., Hydrocarbons from coal: AAPG Studies in Geology 38, p. 39-77.Levine, J.R., 1993, Coalification: the evolution of coal as source rock and reservoir rock for oil and gas, in B.E. Law and D.D. Rice, eds., Hydrocarbons from coal: AAPG Studies in Geology 38, p. 39-77.Levine, J.R., 1993, Coalification: the evolution of coal as source rock and reservoir rock for oil and gas, in B.E. Law and D.D. Rice, eds., Hydrocarbons from coal: AAPG Studies in Geology 38, p. 39-77.Levine, J.R., 1996, Model study of the influence of matrix shrinkage on absolute permeability of coal bed reservoirs, in R. Gayer and I. Harris, eds., Coalbed methane and coal geology: London, Geological Society Special Publication 109, p. 197-212.

Lewan, M.D., 1987, Petrographic study of primary petroleum migration in the Woodford Shale and related rock units, in B. Doligez, ed., Migration of hydrocarbons in sedimentary basins: Paris, Collection Colloques et Séminaires, Editions Technip, p. 113-130.

Leythaeuser, D., H.W. Hagemann, A. Hollerbach, and R.G. Schaefer, 1980, Hydrocarbon generation in source beds as a function of type and maturation of their organic matter: a mass balance approach, in Proceedings of the 10th World Petroleum Congress, v. 2: Philadelphia, Heyden & Son, Inc., p. 31-41.

Li, K., R. Khanna, J. Zhang, Z. Liu, V. Sahajwalla, T. Yang, and D. Kong, 2014, The evolution of structural order, microstructure and mineral matter of metallurgical coke in a blast furnace: A review: Fuel, v. 133, p. 194-215.Li, L., N. Zhao, W. Wei, and Y. Sun, 2013, A review of research progress on CO2 capture, storage, and utilization in Chinese Academy of Sciences: Fuel, v. 108, p. 112-130.

Li, M., J. Bao, R. Lin, L.D. Stasiuk, and M. Yuan, 2001, Revised models for hydrocarbon generation, migration and accumulation in Jurassic coal measures of the Turpan basin, NW China: Organic Geochemistry, v. 32, p. 1127-1151.Li, M., L. Stasiuk, R. Maxwell, F. Monnier, and O. Bazhenova, 2006, Geochemical and petrological evidence for Tertiary terrestrial and Cretaceous marine potential petroleum source rocks in the western Kamchatka coastal margin, Russia: Organic Geochemistry, v. 37, p. 304-320.Li, Q., X. Han, Q. Liu, and X. Jiang, 2014, Thermal decomposition of Huadian oil shale. Part 1. Critical organic intermediates: Fuel, v. 121, p. 109-116.Li, R., K. Jin, and D.J. Lehrmann, 2008, Hydrocarbon potential of Pennsylvanian coal in Bohai Gulf Basin, eastern China, as revealed by hydrous pyrolysis: International Journal of Coal Geology, v. 73, p. 88-97.Li, S., D. Tang, Z. Pan, H. Xu, and W. Huang, 2013, Characterization of the stress sensitivity of pores for different rank coals by nuclear magnetic resonance: Fuel, v. 111, p. 746-754.Li, T., M.F. Cai, and M. Cai, 2007, Earthquake-induced unusual gas emission in coalmines — A km-scale in-situ experimental investigation at Laohutai mine: International Journal of Coal Geology, v. 71, p. 209-224.Li, T.X., H. Ban, J.C. Hower, J.M. Stencel, and K. Saito, 1999, Dry triboelectrostatic separation of mineral particles: a potential application in space exploration: Journal of Electrostatics, v. 47, p. 133-142.Li, W., and Y. Tang, 2014, Sulfur isotopic composition of superhigh-organic-sulfur coals from the Chenxi coalfield, southern China: International Journal of Coal Geology, v. 127, p. 3-13.Li, W., Y. Zhu, S. Chen, and Y. Zhou, 2013, Research on the structural characteristics of vitrinite in different coal ranks: Fuel, v. 107, p. 647-652.Li, W., Y.-P. Cheng, and L. Wang, 2011, The origin and formation of CO2 gas pools in the coal seam of the Yaojie coalfield in China: International Journal of Coal Geology, v. 85, p. 227-236.Li, W., Y.-P. Cheng, and L. Wang, 2011, The origin and formation of CO2 gas pools in the coal seam of the Yaojie coalfield in China: International Journal of Coal Geology, v. 85, p. 227-236.Li, X., S. Dai, W. Zhang, T. Li, X. Zheng, and W. Chen, 2014, Determination of As and Se in coal and coal combustion products using closed vessel microwave digestion and collision/reaction cell technology (CCT) of inductively coupled plasma mass spectrometry (ICP-MS): International Journal of Coal Geology, v. 124, p. 1-4.Li, X., S. Dai, W. Zhang, T. Li, X. Zheng, and W. Chen, 2014, Determination of As and Se in coal and coal combustion products using closed vessel microwave digestion and collision/reaction cell technology (CCT) of inductively coupled plasma mass spectrometry (ICP-MS): International Journal of Coal Geology, v. 124, p. 1-4.Li, Z., A.H. Clemens, T.A. Moore, D. Gong, S.D. Weaver, and N. Eby, 2005, Partitioning behaviour of trace elements in a stoker-fired combustion unit: an example using bituminous coals from the Greymouth coalfield (Cretaceous), New Zealand: International Journal of Coal Geology, v. 63, p. 98-116.Li, Z., C.R. Ward, and L.W. Gurba, 2007, Occurrence of non-mineral inorganic elements in low-rank coal macerals as shown by electron microprobe element mapping techniques: International Journal of Coal Geology, v. 70, p. 137-149.Li, Z., C.R. Ward, and L.W. Gurba, 2007, Occurrence of non-mineral inorganic elements in low-rank coal macerals as shown by electron microprobe element mapping techniques: International Journal of Coal Geology, v. 70, p. 137-149.Li, Z., C.R. Ward, and L.W. Gurba, 2010, Occurrence of non-mineral inorganic elements in macerals of low-rank coals: International Journal of Coal Geology, v. 81, p. 242-250.Li, Z., P.M. Fredericks, C.R. Ward, and L. Rintoul, 2010, Chemical functionalities of high and low sulfur Australian coals: A case study using micro attenuated total reflectance-Fourier transform infrared (ATR-FTIR) spectrometry: Organic Geochemistry, v. 41, p. 554-558.Li, Z., P.M. Fredericks, C.R. Ward, and L. Rintoul, 2010, Chemical functionalities of high and low sulfur Australian coals: A case study using micro attenuated total reflectance-Fourier transform infrared (ATR-FTIR) spectrometry: Organic Geochemistry, v. 41, p. 554-558.Li, Z., P.M. Fredericks, L. Rintoul, and C.R. Ward, 2007, Application of attenuated total reflectance micro-Fourtier transform infrared (ATR-FTIR) spectroscopy to the study of coal macerals: Examples from the Bowen Basin, Australia: International Journal of Coal Geology, v. 70, p. 87-94.Liao, Y., Y. Fang, L. Wu, A. Geng, and C.S. Hsu, 2012, The characteristics of the biomarkers and δ13C of n-alkanes released from thermally altered solid bitumens at various maturities by catalytic hydropyrolysis: Organic Geochemistry, v. 46, p. 56-65.Liebert, J., 2009, Extracting value from coal mine methane: Coal Age, v. 114. No. 6, p. 34-42.Lignum, J., I. Jarvis, and M.A. Pearce, 2008, A critical assessment of standard processing methods for the preparation of palynological samples: Review of Palaeobotany and Palynology, v. 149, p. 133-149. (dinoflagellate)Lille, U., 2004, Behavior of Estonian Kukersite kerogen in molecular mechanical force field: Oil Shale, v. 21, p. 99-114.Lin, R., 1994, An interlaboratory comparison of vitrinite reflectance measurement: Organic Geochemistry, v. 22, p. 1-9.Lin, R., A. Davis, D.F. Bensley, and F.J. Derbyshire, 1986, Vitrinite secondary fluorescence: its chemistry and relation to the development of a mobile phase and thermoplasticity in coal: International Journal of Coal Geology, v. 6, p. 215-228.Lin, R., A. Davis, D.F. Bensley, and F.J. Derbyshire, 1986, Vitrinite secondary fluorescence: its chemistry and relation to the development of a mobile phase and thermoplasticity in coal: International Journal of Coal Geology, v. 6, p. 215-228.Lin, R., A. Davis, D.F. Bensley, and F.J. Derbyshire, 1987, The chemistry of vitrinite fluorescence: Organic Geochemistry, v. 11, p. 393-399.Lin, R., A. Davis, D.F. Bensley, and F.J. Derbyshire, 1987, The chemistry of vitrinite fluorescence: Organic Geochemistry, v. 11, p. 393-399.Lin, R., and A. Davis, 1988, A fluorogeochemical model for coal macerals: Organic Geochemistry, v. 12, p. 363-374.Lin, R., and A. Davis, 1988, A fluorogeochemical model for coal macerals: Organic Geochemistry, v. 12, p. 363-374.Lin, R., and A. Davis, 1988, The chemistry of coal maceral fluorescence: with special reference to the huminite/vitrinite group: The Pennsylvania State University Special Research Report SR-122, 278 p.Lin, S., M. Harada, Y. Suzuki, and H. Hatano, 2002, Hydrogen production from coal by separating carbon dioxide during gasification: Fuel, v. 81, p. 2079-2085.Lincoln, D.L., and S.W. Shin, 2008, Measuring performance in the Powder River Basin: An Investor’s Guide to Unconventional Gas: Shales and Coalbed Methane, Supplement to Oil & Gas Investor, January 2008, p. 26-29.

Link, C.M., 1988, Organic maturation and petroleum source potential of Phanerozoic strata in northern Yukon and northwestern District of Mackenzie: Vancouver, University of British Columbia, unpublished M.S. thesis, 273 p.Link, C.M., R.M. Bustin, and F. Goodarzi, 1990, Petrology of graptolites and their utility as indices of thermal maturity in lower Paleozoic strata in northern Yukon, Canada: International Journal of Coal Geology, v. 15, p. 113-135.Liotta, R., G. Brons, and J. Isaacs, 1983, Oxidative weathering of Illinois No. 6 coal: Fuel, v. 62, p. 781-791.

Li, M., F. Zeng, H. Chang, B. Xu, and W. Wang, 2013, Aggregate structure evolution of low-rank coals during pyrolysis by in-situ X-ray diffraction: International Journal of Coal Geology, v. 116-117, p. 262-269.

Lindahl, P.C., and R.B. Finkelman, 1986, Factors influencing major, minor and trace element variations in U.S. coals, in K.S. Vorris, ed., Mineral matter and ash in coal: Washington, D.C., American Chemical Society, ACS Symposium Series 301, p. 61-69.

Lis, G.P., M. Mastalerz, A. Schimmelmann, M.D. Lewan, and B.A. Stankiewicz, 2005, FTIR absorption indices for thermal maturity in comparison with vitrinite reflectance Ro in type-II kerogens from Devonian black shales: Organic Geochemistry, v. 36, p. 1533-1552.Littke, R., 1993, Deposition, diagenesis and weathering of organic matter-rich sediments: New York, Springer-Verlag, 216 p. (porosity is minimum in mvb coals)Littke, R., 1993, Deposition, diagenesis and weathering of organic matter-rich sediments: New York, Springer-Verlag, Lecture Notes in Earth Sciences 47, 216 p.

Littke, R., and H.L. ten Haven, 1989, Palaeoecologic trends and petroleum potential of Upper Carboniferous coal seams of western Germany as revealed by their petrographic and organic geochemical characteristics: International Journal of Coal Geology, v. 13, p. 529-574.Littke, R., B. Horsfield, and D. Leythaeuser, 1989, Hydrocarbon distribution in coals and dispersed organic matter of different maceral composition and maturities: Geol. Rundschau, v. 78, p. 391-410.

Littke, R., D.R. Baker, and D. Leythaeuser, 1988, Microscopic and sedimentologic evidence for the generation and migration of hydrocarbons in Toarcian source rocks of different maturities: Organic Geochemistry, v. 13, p. 549-559. (metaalginite)Littke, R., H.L. ten Haven, and D. Leythaeuser, 1990, Paleoecological trends and petroleum potential of Upper Carboniferous coal seams of western Germany: International Journal of Coal Geology, v. 16, p. 197-200.Littke, R., J.L. Urai, A.K. Uffmann, and F. Risvanis, 2012, Reflectance of dispersed vitrinite in Palaeozoic rocks with and without cleavage: Implications for burial and thermal history modeling in the Devonian of Rursee area, northern Rhenish Massif, Germany: International Journal of Coal Geology, v. 89, p. 41-50.Littke, R., U. Klussmann, B. Krooss, and D. Leythaeuser, 1991, Quantification of loss of calcite, pyrite, and organic matter due to weathering of Toarcian black shales and effects on kerogen and bitumen characteristics: Geochimica et Cosmochimica Acta, v. 55, p. 3369-3378.

Litwin, R.J., and S.R. Ash, 1991, First early Mesozoic amber in the western hemisphere: Geology, v. 19, p. 273-276.Liu, A., X. Fu, K. Wang, H. An, and G. Wang, 2013, Investigation of coalbed methane potential in low-rank coal reservoirs—Free and soluble gas contents: Fuel, v. 112, p. 14-22.Liu, C., C. Che, J. Zhu, and H. Yang, 2010, China’s endowment—2. China assesses unconventional land oil shale, oil sands, coal gas resources: Oil & Gas Journal, v. 108.15, p. 36-39.Liu, C., C. Che, J. Zhu, and H. Yang, 2010, China’s endowment—2. China assesses unconventional land oil shale, oil sands, coal gas resources: Oil & Gas Journal, v. 108.15, p. 36-39.Liu, C.J., G.X. Wang, S.X. Sang, and V. Rudolph, 2010, Changes in pore structure of anthracite coal associated with CO2 sequestration process: Fuel, v. 89, p. 2665-2672.Liu, D., 1995, A study on composition and structure of graptolites using MICRO-FTIR and TOF-SIMS: Scientia Geologica Sinica, v. 4, no. 1, p. 105-110.Liu, D., and P. Peng, 2008, Possible chemical structures and biological precursors of difference vitrinites in coal measure in northwest China: International Journal of Coal Geology, v. 75, p. 204-212.Liu, D., Y. Yao, D. Tang, S. Tang, Y. Che, and W. Huang, 2009, Coal reservoir characteristics and coalbed methane resource assessment in Huainan and Huaibei coalfields, southern north China: International Journal of Coal Geology, v. 79, p. 97-112.Liu, G., L. Zheng, Y. Zhang, C. Qi, Y. Chen, and Z. Peng, 2007, Distribution and mode of occurrence of As, Hg and Se and sulfur in coal seam 3 of the Shanxi Formation, Yanzhou coalfield, China: International Journal of Coal Geology, v. 71, p. 371-385.Liu, J., J. Wang, Z. Chen, S. Wang, D. Elsworth, and Y. Jiang, 2011, Impact of transition from local swelling to macro swelling on the evolution of coal permeability: International Journal of Coal Geology, v. 88, p. 31-40.Liu, J., X. Jiang, X. Huang, and S. Wu, 2010, Morphological characterization of super fine pulverized coal particle. Part 2. AFM investigation of single coal particle: Fuel, v. 89, p. 3884-3891.Liu, J., Z. Chen, D. Elsworth, H. Qu, and D. Chen, 2011, Interactions of multiple processes during CBM extraction: a critical review: International Journal of Coal Geology, v. 87, p. 175-189.Liu, J., Z. Chen, D. Elsworth, X. Miao, and X. Mao, 2010, Evaluation of stress-controlled coal swelling processes: International Journal of Coal Geology, v. 83, p. 446-455.Liu, J., Z. Chen, D. Elsworth, X. Miao, and X. Mao, 2010, Linking gas-sorption induced changes in coal permeability to directional strains through a modulus reduction ratio: International Journal of Coal Geology, v. 83, p. 21-30.Liu, J., Z. Chen, D. Elsworth, X. Miao, and X. Mao, 2010, Linking gas-sorption induced changes in coal permeability to directional strains through a modulus reduction ratio: International Journal of Coal Geology, v. 83, p. 21-30.Liu, S., and S. Harpalani, 2013, Permeability prediction of coalbed methane reservoirs during primary depletion: International Journal of Coal Geology, v. 113, p. 1-10.Liu, S., C. Wang, S. Zhang, J. Liang, F. Chen, and K. Zhao, 2012, Formation and distribution of polycyclic aromatic hydrocarbons (PAHs) derived from coal seam combustion: A case study of the Ulanqab lignite from Inner Mongolia, northern China: International Journal of Coal Geology, v. 90-91, p. 126-134.

Liu, S., S. Harpalani, and M. Pillalamarry, 2012, Laboratory measurement and modeling of coal permeability with continued methane production: Part 2 – Modeling results: Fuel, v. 94, p. 117-124.Liu, Y., and J. Wilcox, 2012, Molecular simulation of CO2 adsorption in micro- and mesoporous carbons with surface heterogeneity: International Journal of Coal Geology, v. 104, p. 83-95.Liu, Y., M.A. Urynowicz, and D.M. Bagley, 2013, Ethanol conversion to methane by a coal microbial community: International Journal of Coal Geology, v. 115, p. 85-91.Liu, Y.-K., F.-B. Zhou, L. Liu, C. Liu, and S.-Y. Hu, 2011, An experimental and numerical investigation on the deformation of overlying coal seams above double-seam extraction for controlling coal mine methane emissions: International Journal of Coal Geology, v. 87, p. 139-149.Lloyd, W.G., J.T. Riley, M.A. Risen, S.R. Gilleland, and R.L. Tibbitts, 1993, Estimation of ash fusion temperatures: Journal of Coal Quality, v. 12, p. 30-36.Lloyd, W.G., J.W. Reasoner, J.C. Hower, and L.P. Yates, 1989, Effects of pressure upon the isothermal plastic behavior of high-volatile bituminous Kentucky coals: Journal of Energy and Fuels, v. 3, p. 585-589.Lloyd, W.G., J.W. Reasoner, J.C. Hower, and L.P. Yates, 1990, Estimates of fluid properties of high volatile bituminous coals: Fuel, v. 69, p. 1257-1270.Lo, H.-B., 1987, A quantitative fluorescence technique for evaluating thermal maturity: instrumentation and examples: Organic Geochemistry, v. 11, p. 371-377.Lo, H.-B., 1988, Photometric methods for measuring the thermal maturity on strew-mounted kerogen slides: Organic Geochemistry, v. 12, p. 303-307.

Lipps, J.H., 1993, Appendix: collection and preparation techniques, in J.H. Lipps, ed., Fossil prokaryotes and protists: Boston, Blackwell Scientific Publications, p. 305-310.

Littke, R., and D. Leythaeuser, 1993, Migration of oil and gas in coals, in B.E. Law and D.D. Rice, eds., Hydrocarbons from coal: AAPG Studies in Geology 38, p. 219-236.Littke, R., and D. Leythaeuser, 1993, Migration of oil and gas in coals, in B.E. Law and D.D. Rice, eds., Hydrocarbons from coal: AAPG Studies in Geology 38, p. 219-236.

Littke, R., D. Leythaeuser, M. Radke, and R.G. Schaefer, 1990, Petroleum generation and migration in coal seams of the Carboniferous Ruhr basin, northwest Germany, in B. Durand and F. Behar, eds., Advances in organic geochemistry 1989, part I, organic geochemistry in petroleum exploration: Organic Geochemistry, v. 16, p. 247-258.

Litwin, R.J., and A. Traverse, 1989, Basic guidelines for palynomorph extraction and preparation from sedimentary rocks, in R.M. Feldmann, R.E. Chapman, and J.T. Hannibal, eds., Paleotechniques: The Paleontological Society Special Publication 4, p. 87-98.

Liu, S., G.H. Taylor, and M. Shibaoka, 1982, Biochemical gelification and the nature of some huminite macerals, in C.W. Mallett, ed., Coal resources: origin, exploration and utilization in Australia, Proceedings: Geological Society of Australia Coal Group, Symposium, p. 145-152.

Lo, H.-B., 1988, Photometric methods for measuring the thermal maturity on strew-mounted kerogen slides: Organic Geochemistry, v. 12, p. 303-307.Lo, H.-B., 1991, How well can artificial coalification simulate the natural maturation trend?: Organic Geochemistry, v. 17, p. 415-420.Lo, H.B., 1991, Types of vitrinite macerals II: identification of indigenous vitrinites for improved thermal maturity evaluation: TSOP Newsletter, v. 8, no. 1, p. 12-14.Lo, H.-B., 1992, Identification of indigenous vitrinites for improved thermal maturity evaluation: Organic Geochemistry, v. 18, p. 359-364.Lo, H.-B., 1993, Correction criteria for the suppression of vitrinite reflectance in hydrogen-rich kerogens: preliminary guidelines: Organic Geochemistry, v. 20, p. 653-657.Lo, H.-B., 1993, Correction criteria for the suppression of vitrinite reflectance in hydrogen-rich kerogens: preliminary guidelines: Organic Geochemistry, v. 20, p. 653-657.Lo, H.-B., 1998, How to evaluate maturity of kerogen when its vitrinite reflectance is suppressed (abstract): TSOP, Abstracts and Program, v. 15, p. 42-43.Lo, H.B., and B.J. Cardott, 1994, Detection of natural weathering of Upper McAlester coal and Woodford Shale, Oklahoma, U.S.A.: Organic Geochemistry, v. 22, p. 73-83.Lo, H.B., R.W.T. Wilkins, M.V. Ellacott, and C.P. Buckingham, 1997, Assessing the maturity of coals and other rocks from North America using the fluorescence alteration of multiple macerals (FAMM) technique: International Journal of Coal Geology, v. 33, p. 61-71.Lobzova, R.V., and T.A. Ziborova, 1988, Behavior of high-carbon solid during metamorphism: International Geology Review, v. 30, p. 187-196.

Lomando, A.J., 1992, The influence of solid reservoir bitumen on reservoir quality: AAPG Bulletin, v. 76, p. 1137-1152.Lombardi, T., L. Baez, W. Drexler, and C. Hoffman, 2004, Western Interior Coal Region, geologic overview and corehole results: Tuscaloosa, Alabama, University of Alabama, College of Continuing Studies, 2004 International Coalbed Methane Symposium Proceedings, paper 0430, 16 p.López Antón, M.A., D.A. Spears, M. Díaz Somoano, and M.R. Martínez-Tarazona, 2013, Thallium in coal: Analysis and environmental implications: Fuel, v. 105, p. 13-18.Lopez, D., Y. Sanada, and F. Mondragon, 1998, Effect of low-temperature oxidation of coal on hydrogen-transfer capability: Fuel, v. 77, p. 1623-1628.López, I.C., and C.R. Ward, 2008, Composition and mode of occurrence of mineral matter in some Colombian coals: International Journal of Coal Geology, v. 73, p. 3-18.López-Antón, M.A., M. Díaz-Somoano, R. Ochoa-González, and M.R. Martínez-Tarazona, 2012, Analytical methods for mercury analysis in coal and coal combustion by-products: International Journal of Coal Geology, v. 94, p. 44-53.López-Antón, M.A., M. Díaz-Somoano, R. Ochoa-González, and M.R. Martínez-Tarazona, 2012, Analytical methods for mercury analysis in coal and coal combustion by-products: International Journal of Coal Geology, v. 94, p. 44-53.López-Buendía, A.M., M.K.G. Whateley, J. Bastida, and M.M. Urquiola, 2007, Origins of mineral matter in peat marsh and peat bog deposits, Spain: International Journal of Coal Geology, v. 71, p. 246-262.López-Días, V., J. Urbanczyk, C.G. Blanco, and A.G. Borrego, 2013, Biomarkers as paleoclimate proxies in peatlands in coastal high plains in Asturias, N. Spain: International Journal of Coal Geology, v. 116-117, p. 270-280.Lorente, M.A., 1991, The Amsterdam palynological organic matter classification, International Committee for Palynological Organic Matter Classification: TSOP Newsletter, v. 8, no. 3, p. 6-7.Lottes, A.L., and A.M. Ziegler, 1994, World peat occurrence and the seasonality of climate and vegetation: Palaeogeography, Palaeoclimatology, Palaeoecology, v. 106, p. 23-37.Lough, K., and S. Jewell, 2007, CBM grows in Scotland: An entrepreneur seeks to tap Scotland’s coals for methane: Hart’s E&P, v. 80, no. 6, p. 95-96.Love, A.H., 1977, Kerogen-isolation and thermal maturation study in sedimentary rock sections: Colorado School of Mines, unpublished M.S. thesis, 34 p.Lowenhaupt, D.E., and R.J. Gray, 1980, The alkali-extraction test as a reliable method of detecting oxidized metallurgical coal: International Journal of Coal Geology, v. 1, p. 63-73.Lowry, H.H., 1942, Relation of the physical constitution of coal to its chemical characteristics: Journal of Geology, v. 50, p. 357-384.Lowry, H.H., 1942, Relation of the physical constitution of coal to its chemical characteristics: Journal of Geology, v. 50, p. 357-384.Lowry, H.H., ed., 1945, Chemistry of coal utilization, v. 1 and 2: New York, John Wiley & Sons, Inc., 1868 p.Lu, J., K. Milliken, R.M. Reed, and S. Hovorka, 2011, Diagenesis and sealing capacity of the middle Tuscaloosa mudstone at the Cranfield CO2 injection site, Mississippi, USA: Environmental Geosciences Journal, v. 18, no. 1.Lu, P., Q. Fu, W.E. Seyfried, S.W. Hedges, Y. Soong, K. Jones, and C. Zhu, 2013, Coupled alkali feldspar dissolution and secondary mineral precipitation in batch systems—2: New experiments with supercritical CO2 and implications for carbon sequestration: Applied Geochemistry, v. 30, p. 75-90.Lu, S.-T., and I.R. Kaplan, 1990, Hydrocarbon-generating potential of humic coals from dry pyrolysis: AAPG Bulletin, v. 74, p. 163-173.Lu, S.-T., and I.R. Kaplan, 1992, Diterpanes, triterpanes, steranes, and aromatic hydrocarbons in natural bitumens and pyrolysates from different humic coals: Geochimica et Cosmochimica Acta, v. 56, p. 2761-2788.Lu, T., H. Yu, T. Zhou, J. Mao, and B. Guo, 2009, Improvement of methane drainage in high gassy coal seam using waterjet technique: International Journal of Coal Geology, v. 79, p. 40-48.Lü, X., Y. Sun, T. Lu, F. Bai, and M. Viiljanen, 2014, An efficient and general analytical approach to modelling pyrolysis kinetics of oil shale: Fuel, v. 135, p. 182-187.Lu, Y., Y. Liu, X. Li, and Y. Kang, 2010, A new method of drilling long boreholes in low permeability coal by improving its permeability: International Journal of Coal Geology, v. 84, p. 94-102.Lubick, N., 2005, Getting bitumen flowing: Geotimes, v. 49, no. 12, p. 22-23.Lucas, A.J., P.H. Given, and W. Spackman, 1988, Studies of peat as the input to coalification, I. Rationale and preliminary examination of polysaccharides in peats: International Journal of Coal Geology, v. 9, p. 235-251.Ludvig, M.M., G.L. Gard, and P.H. Emmett, 1983, Use of controlled oxidation to increase the surface area of coal. Applications to a bituminous and a semi-anthracite coal: Fuel, v. 62, p. 1393-1396.Luo, G., J. Ma, J. Han, H. Yao, M. Xu, C. Zhang, G. Chen, R. Gupta, and Z. Xu, 2013, Hg occurrence in coal and its removal before coal utilization: Fuel, v. 104, p. 70-76.

Logan, T.L., 1988, Horizontal drainhole drilling techniques used in Rocky Mountain coal seams, in J.E. Fassett, ed., Geology and coal-bed methane resources of the northern San Juan basin, Colorado and New Mexico: Denver, Rocky Mountain Association of Geologists Guidebook, p. 133-141.Logan, T.L., 1993, Drilling techniques for coalbed methane, in B.E. Law and D.D. Rice, eds., Hydrocarbons from coal: AAPG Studies in Geology 38, p. 269-285.Logan, T.L., W.F. Clark, and R.A. McBane, 1992, Comparing openhole cavity and cased hole hydraulic fracture completion techniques, San Juan basin, New Mexico, in Coalbed methane: Society of Petroleum Engineers, Reprint Series 35, p. 139-146.

Luo, K., D. Ren, L. Xu, S. Dai, D. Cao, F. Feng, and J. Tan, 2004, Fluorine content and distribution pattern in Chinese coals: International Journal of Coal Geology, v. 57, p. 143-149.Luo, Q., N. Zhong, J. Qin, K. Li, Y. Zhang, Y. Wang, and L. Ma, 2014, Thucholite in Mesoproterozoic shales from northern north China: Occurrence and indication for thermal maturity: International Journal of Coal Geology, v. 125, p. 1-9. [thucholite is uranium-bearing pyrobitumen]Luppens, J.A., and A.P. Hoeft, 1991, Relationship between inherent and equilibrium moisture contents in coals by rank: Journal of Coal Quality, v. 10, p. 133-141.Luppens, J.A., S.E. Wilson, and R.W. Stanton, eds., 1992, Manual on drilling, sampling, and analysis of coal: Philadelphia, PA, ASTM Manual Series MNL 11, 61 p.Luppens, J.A.., D.C. Scott, L.M. Osmonson, J.E. Haacke, and P.E. Pierce, 2013, Assessment of coal geology, resources, and reserve base in the Powder River Basin, Wyoming and Montana: U.S. Geological Survey, Fact Sheet 2012-3143, 6 p.Lv, Y., D. Tang, H. Xu, and H. Luo, 2012, Production characteristics and the key factors in high-rank coalbed methane fields: A case study on the Fanzhuang Block, southern Qinshui Basin, China: International Journal of Coal Geology, v. 96-97, p. 93-108.Lyle, D., 2007, CO2 can tap residual oil zone: Hart’s E&P, v. 80, no. 6, p. 75-76.Lyle, D., 2007, CO2 research promises oil gains: Harts E&P, v. 80, no. 12, p. 56, 58.Lyle, D., 2007, Enhanced gas recovery works: Hart’s E&P, v. 80, no. 6, p. 79-80.Lyle, D., 2007, Enhanced gas recovery works: Worldwide efforts aim at increased coalbed methane recovery with CO2 sequestration: Hart’s E&P, v. 80, no. 6, p. 70.Lyle, D., 2007, Maturity encourages refinement: No longer a new play, coalbed methane technology spreads worldwide: Hart’s E&P, v. 80, no. 6, p. 91-92.Lyman, R.M., 2001, Pyrophoricity (spontaneous combustion) of Powder River basin coals — considerations for coalbed methane development: Wyoming Geo-Notes, number 69, p. 18-22.Lyman, R.M., 2001, Pyrophoricity (spontaneous combustion) of Powder River basin coals — considerations for coalbed methane development: Wyoming Geo-Notes, number 69, p. 18-22.Lyon, D.A., and R.M. Keeney, 1914, Electric furnaces for making iron and steel: U.S. Bureau of Mines, Bulletin 67, 142 p.Lyons, P. C., and C.L. Rice, eds., 1986, Paleoenvironmental and tectonic controls on coal-forming basins in the United States: Geological Society of America Special Paper 210, 200 p.Lyons, P.C., 1991, Bacteria-like bodies in coalified Carboniferous xylem—enigmatic microspheroids or possible evidence of microbial saprophytes in a vitrinite precursor?: International Journal of Coal Geology, v. 18, p. 293-303.Lyons, P.C., 1996, Coalbed methane potential in the Appalachian states of Pennsylvania, West Virginia, Maryland, Ohio, Virginia, Kentucky, and Tennessee — an overview: U.S. Geological Survey Open-File Report 96-735 (available on the internet; discusses ownership of coalbed methane)

Lyons, P.C., 2000, Funginite and secretinite—two new macerals of the inertinite maceral group: International Journal of Coal Geology, v. 44, p. 95-98.Lyons, P.C., 2003, The maceral term "Sclerotinite" has been officially abandoned by the ICCP: ICCP News, No. 28, p. 17-19.Lyons, P.C., and A.T. Cross, 2005, In memoriam Hugh J. O’Donnell (1910-2004) Pioneer in coal petrography: TSOP Newsletter, v. 22, no. 4, p. 14-15.Lyons, P.C., and B. Alpern, eds., 1989, Coal: classification, coalification, mineralogy, trace-element chemistry, and oil and gas potential: International Journal of Coal Geology, v. 13, 626 p.Lyons, P.C., and B. Alpern, eds., 1989, Peat and coal: origin, facies, and depositional models: International Journal of Coal Geology, v. 12, 798 p.Lyons, P.C., and B. Alpern, eds., 1989, Peat and coal: origin, facies, and depositional models: New York, Elsevier Science Publishers, 882 p.Lyons, P.C., and C.L. Rice, eds., 1986, Paleoenvironmental and tectonic controls in coal-forming basins in the United States: Geological Society of America Special Paper 210, 200 p.Lyons, P.C., and E.L. Zodrow, eds., 1997, Euramerican Carboniferous paleobotany and coal geology: Review of Palaeobotany and Palynology, v. 95, 304 p.Lyons, P.C., and M. Mastalerz, 2001, Secretinite—reflectance and chemical data from two high volatile bituminous coals (upper Carboniferous) of North America: International Journal of Coal Geology, v. 45, p. 281-287.Lyons, P.C., and M. Teichmuller, 1995, Reinhardt Thiessen (1867-1938): Pioneering coal petrologist and stratigraphic palynologist: Geological Society of America Memoir 185.Lyons, P.C., and R.T. Ryder, 1995, Selected bibliography of Appalachian coalbed methane: U.S. Geological Survey, Open-File Report 95-572.Lyons, P.C., C.A. Palmer, N.H. Bostick, J.D. Fletcher, F.T. Dulong, F.W. Brown, Z.A. Brown, M.R. Krasnow, and L.A. Romankiw, 1989, Chemistry and origin of minor and trace elements in vitrinite concentrates from a rank series from the eastern United States, England, and Australia: International Journal of Coal Geology, v. 13, p. 481-527.Lyons, P.C., C.A. Palmer, R.M. Bustin, and A.M. Vassallo, eds., 1996, New techniques in the chemical analysis of coal: International Journal of Coal Geology, v. 32, 312 p.Lyons, P.C., C.L. Thompson, P.G. Hatcher, and F.W. Brown, 1984, Coalification of organic matter in coal balls of the Pennsylvanian (upper Carboniferous) of the Illinois Basin, United States: Organic Geochemistry, v. 5, p. 227-239.Lyons, P.C., D.A. Spears, W.F. Outerbridge, R.D. Congdon, and H.T. Evans, Jr., 1994, Euramerican tonsteins: overview, magmatic origin, and depositional-tectonic implications: Palaeogeography, Palaeoclimatology, Palaeoecology, v. 106, p. 113-134.Lyons, P.C., D.A. Spears, W.F. Outerbridge, R.D. Congdon, and H.T. Evans, Jr., 1994, Euramerican tonsteins: overview, magmatic origin, and depositional-tectonic implications: Palaeogeography, Palaeoclimatology, Palaeoecology, v. 106, p. 113-134.

Lyons, P.C., E.L. Zodrow, M.A. Millay, G. Dolby, K.S. Gillis, and A.T. Cross, 1997, Coal-ball floras of Maritime Canada and palynology of the Foord seam: geologic, paleobotanical and paleoecological implications: Review of Palaeobotany and Palynology, v. 95, p. 31-50.

Lyons, P.C., M.A. Millay, E.L. Zodrow, A.T. Cross, and K.S. Gillis, 1995, Discovery of permineralized plant fossils (coal balls) in the Bolsovian (ex Westphalian C)(Middle Pennsylvanian, Upper Carboniferous), Stellarton basin, Nova Scotia, Canada: Canadian Journal of Botany, v. 73, p. 1407-1416.Lyons, P.C., P.G. Hatcher, and F.W. Brown, 1986, Secretinite: a proposed new maceral of the inertinite maceral group: Fuel, v. 65, p. 1094-1098.Lyons, P.C., P.G. Hatcher, J.A. Minkin, C.L. Thompson, R.R. Larson, Z.A. Brown, and R.N. Pheifer, 1984, Resin rodlets in shale and coal (Lower Cretaceous), Baltimore Canyon Trough: International Journal of Coal Geology, v. 3, p. 257-278.Lyons, P.C., R.B. Finkelman, C.L. Thompson, F.W. Brown, and P.G. Hatcher, 1982, Properties, origin and nomenclature of rodlets of the inertinite maceral group in coals of the central Appalachian Basin, U.S.A.: International Journal of Coal Geology, v. 1, p. 313-346.

Lyons, P.C., 1998, The central and northern Appalachian basin — a frontier region for coalbed methane development, in P.C. Lyons, ed., Special issue: Appalachian coalbed methane: International Journal of Coal Geology, v. 38, p. 61-87.

Lyons, P.C., E.L. Zodrow, M.A. Millay, G. Dolby, K.S. Gillis, and A.T. Cross, 1997, Coal-ball floras of Maritime Canada and palynology of the Foord seam: geologic, paleobotanical and paleoecological implications, in P.C. Lyons and E.L. Zodrow, eds., Euramerican Carboniferous paleobotany and coal geology: Review of Palaeobotany and Palynology, v. 95, p. 31-50.

Lyons, P.C., M. Mastalerz, and W.H. Orem, 2009, Organic geochemistry of resins from modern Agathis australis and Eocene resins from New Zealand: Diagenetic and taxonomic implications: International Journal of Coal Geology, v. 80, p. 51-62.

Lyons, P.C., R.B. Finkelman, C.L. Thompson, F.W. Brown, and P.G. Hatcher, 1982, Properties, origin and nomenclature of rodlets of the inertinite maceral group in coals of the Central Appalachian basin, U.S.A.: International Journal of Coal Geology, v. 1, p. 313-346.

Lyons, P.C., T.G. Callcott, and B. Alpern, eds., 1990, Peat and coal: origin, facies, and coalification: International Journal of Coal Geology, v. 16, 237 p.Lyons, P.C., W.F. Outerbridge, D.M. Triplehorn, H.T. Evans, Jr., R.D. Congdon, M. Capiro, J.C. Hess, and W.P. Nash, 1992, An Appalachian isochron: a kaolinized Carboniferous air-fall volcanic-ash deposit (tonstein): Geological Society of America Bulletin, v. 104, p. 515-1527.Lyons, W.S., 2001, Seismic maps Ferron coalbed sweetspots: AAPG Explorer, v. 22, no. 12, p. 32-37.Ma, Q., S. Harpalani, and S. Liu, 2011, A simplified permeability model for coalbed methane reservoirs based on matchstick strain and constant volume theory: International Journal of Coal Geology, v. 85, p. 43-48.Macauley, G., 1981, Geology of the oil shale deposits of Canada: Geological Survey of Canada Open-File Report OF 754, 155 p.Macauley, G., L.R. Snowdon, and F.D. Ball, 1985, Geochemistry and geological factors governing exploitation of selected Canadian oil shale deposits: Geological Survey of Canada Paper 85-13, 65 p.Macauley, G., M.G. Fowler, F. Goodarzi, L.R. Snowdon, and L.D. Stasiuk, 1990, Ordovician oil shale-source rock sediments in the central and eastern Canada mainland and eastern Arctic areas, and their significance for frontier exploration: Geological Survey of Canada Paper 90-14, 51 p.

Mach, K., I. Sýkorová, M. Konzalová, and A. Opluštil, 2013, Effect of relative lake-level changes in mire-lake system on the petrographic and floristic compositions of a coal seam, in the Most Basin (Miocene), Czech Republic: International Journal of Coal Geology, v. 105, p. 120-136.

Machnikowska, H., A. Krztoń, and J. Machnikowski, 2002, The characterization of coal macerals by diffuse reflectance infrared spectroscopy: Fuel, v. 81, p. 245-252.

Mackowsky, M.-T., 1977, Prediction methods in coal and coke microscopy: Journal of Microscopy, v. 109, pt. 1, p. 119-136.

Mackowsky, M.-T., 1983, The application of coal petrology: Special Publication of the Geological Society of South Africa, v. 7, p. 97-109.

Mackowsky, M.-Th., 1975, Comparative petrography of Gondwana and northern hemisphere coals related to their origin: Proceedings, Third International Gondwana Symposium, Canberra, p. 195-220.Macuda, J., A. Nodzeński, M. Wagner, and L. Zawisza, 2011, Sorption of methane on lignite from Polish deposits: International Journal of Coal Geology, v. 87, p. 41-48. (biogenic methane)

Mahadevan, V., and P.S.M. Tripathi, 1995, Pretreatment of coal, potentiality of microwave and Gamma Ray pretreatments in the desulphurization, demineralization and comminution: Erdol und Kohle-Erdgas-Petrochemie, v. 48, p. 33-38.

Mahanjane, E.S., D. Franke, R. Lutz, J. Winsemann, A. Ehrhardt, K. Berglar, and C. Reichert, 2014, Maturity and petroleum systems modelling in the offshore Zambezi delta depression and Angoche Basin, northern Mozambique: Journal of Petroleum Geology, v. 37, p. 329-348.Maiti, D., P.K. Mazumdar, and S. Sarkar, 2014, Optimization of drilling parameters in Raniganj Formation, Essar Coal Bed Methane Block — a case study: Journal of Unconventional Oil and Gas Resources, v. 6, p. 28-33.Majewska, Z., and J. Ziętek, 2007, Changes of acoustic emission and strain in hard coal during gas sorption–desorption cycles: International Journal of Coal Geology, v. 70, p. 305-312.Majewska, Z., and J. Ziętek, 2007, Changes of acoustic emission and strain in hard coal during gas sorption–desorption cycles: International Journal of Coal Geology, v. 70, p. 305-312.Majewska, Z., G. Ceglarska-Stefańska, S. Majewski, and J. Ziętek, 2009, Binary gas sorption/desorption experiments on a bituminous coal: Simultaneous measurements on sorption kinetics, volumetric strain and acoustic emission: International Journal of Coal Geology, v. 77, p. 90-102.Majewska, Z., S. Majewski, and J. Ziętek, 2010, Swelling of coal induced by cyclic sorption/desorption of gas: experimental observations indicating changes in coal structure due to sorption of CO2 and CH4: International Journal of Coal Geology, v. 83, p. 475-483.Majewska, Z., S. Majewski, and J. Ziętek, 2013, Swelling and acoustic emission behavior of unconfined and confined coal during sorption of CO2: International Journal of Coal Geology, v. 116-117, p. 17-25.Majumder, A.K., R. Jain, P. Banerjee, and J.P. Barnwal, 2008, Development of a new proximate analysis based correlation to predict calorific value of coal: Fuel, v. 87, p. 3077-3081.Maksoud, J., 2008, Raising the Cherokee Basin’s CBM profile: Hart’s E&P, v. 81, no. 6, p. 77-79.Malinconico, M.A.L., 1992, Graptolite reflectance in the prehnite-pumpellyite zone of northern Maine, U.S.A.: Organic Geochemistry, v. 18, p. 263-271.Malinconico, M.A.L., 1993, Reflectance cross-plot analysis of graptolites from the anchi-metamorphic region of northern Maine, U.S.A.: Organic Geochemistry, v. 20, p. 197-207.Malinconico, M.L., 2000, Using reflectance crossplots and rotational polarization for determining first-cycle vitrinite for maturation studies: International Journal of Coal Geology, v. 43, p. 105-120.Malinconico, M.L., 2000, Using reflectance crossplots and rotational polarization for determining first-cycle vitrinite for maturation studies: International Journal of Coal Geology, v. 43, p. 105-120.

Malone, P.G., F.H. Briscoe, B.S. Camp, and C.M. Boyer, II, 1987, Methods of calculating coalbed methane reserves with insight into the advantages and disadvantages of each method: Tuscaloosa, Alabama, Proceedings of the 1987 Coalbed Methane Symposium, paper 8716, p. 73-79.Malone, P.G., L.K. Lottman, B.S. Camp, and J.L. Smith, 1989, An investigation of parameters affecting desorption rates of Warrior basin coals: Tuscaloosa, Alabama, Proceedings of the 1989 Coalbed Methane Symposium, paper 8921, p. 35.Malone, R.D., and C.W. Byrer, 1981, Methane recovery from coalbeds well description and field activities log procedures manual: USDOE Morgantown Energy Technology Center, Technical Progress Report 82-3, 73 p.Malvadkar, S.B., S. Forbes, and G.V. McGurl, 2004, Formation of coal resources: Boston, Elsevier Academic Press, Encyclopedia of Energy, vol. 1, p. 529-550.

Lyons, P.C., T.E. Krogh, Y.Y. Kwok, D.W. Davis, W.F. Outerbridge, and H.T. Evans, Jr., 2006, Radiometric ages of the Fire Clay tonstein [Pennsylvanian (Upper Carboniferous), Westphalian, Duckmantian]: a comparison of U-Pb zircon single-crystal ages and 40Ar/39Ar sanidine single-crystal plateau ages: International Journal of Coal Geology, v. 67, p. 259-266.

Macgregor, D.S., 1994, Coal-bearing strata as source rocks - a global overview, in A.C. Scott and A.J. Fleet, eds., Coal and coal-bearing strata as oil-prone source rocks?: London, The Geological Society Special Publication 77, p. 107-116.

Machel, H.G., R.A. Mason, A.N. Mariano, and A. Mucci, 1991, Causes and emission of luminescence in calcite and dolomite, in C.E. Barker and O.C. Kopp, eds., Luminescence microscopy and spectroscopy: qualitative and quantitative applications: SEPM Short Course 25, p. 9-25.

Mackowsky, M.-T., 1968, Mineral matter in coal, in D.G. Murchison and T.S. Westoll, eds., Coal and coal-bearing strata: Edinburgh, p. 309-321.

Mackowsky, M.-T., 1982, Minerals and trace elements occurring in coal, in Stach’s textbook of coal petrology, third revised and enlarged edition: Berlin, Gebruder Borntraeger, p. 153-171.

Mackowsky, M.-T., and E.-M. Wolff, 1966, Microscopic investigations of pore formation during coking, in R.F. Gould, ed., Coal science: American Chemical Society, Advances in Chemistry Series 55, p. 527-548.

Magoon, L.B., and K.J. Bird, 1988, Evaluation of petroleum source rocks in the National Petroleum Reserve in Alaska, using organic-carbon content, hydrocarbon content, visual kerogen, and vitrinite reflectance, in G. Cryc, ed., Geology and exploration of the National Petroleum Reserve in Alaska, 1974-1982: USGS Professional Paper 1399, p. 381-450.

Mahajan, O.P., and P.L. Walker, Jr., 1978, Porosity of coals and coal products, in C. Karr, Jr., ed., Analytical methods for coal and coal products: New York, Academic Press, p. 125-162.

Malinconico, M.L., 2003, Estimates of eroded strata using borehole vitrinite reflectance data, Triassic Taylorsville rift basin, Virginia: Implications for duration of synrift sedimentation and evidence of structural inversion, in P.M. Letourneau and P.E. Olsen, eds., The great rift valleys of Pangea in eastern North America; v. 1. Tectonics, structure, and volcanism: New York, Columbia University Press, p. 80-103.

Mamay, S.H., 1954, Two new plant genera of Pennsylvanian age from Kansas coal balls: USGS Professional Paper 254-D, p. 81-95.Mamay, S.H., and E.L. Yochelson, 1953, Floral-faunal associations in American coal balls: Science, v. 118, p. 240-241.Mamay, S.H., and E.L. Yochelson, 1962, Occurrence and significance of marine animal remains in American coal balls: U.S. Geological Survey Professional Paper 354-I, p. 193-224.Mancuso, J.J., and R.E. Seavoy, 1981, Precambrian coal or anthraxolite: a source for graphite in high-grade schists and gneisses: Economic Geology, v. 76, p. 951-954.Mancuso, J.J., W.A. Kneller, and J.A. Quick, 1989, Precambrian vein pyrobitumen: evidence for petroleum generation and migration 2 Ga ago: Precambrian Research, v. 44, p. 137-146.Mandile, A.J., and A.C. Hutton, 1995, Quantitative x-ray diffraction analysis of mineral and organic phases in organic-rich rocks: International Journal of Coal Geology, v. 28, p. 51-69.Mangena, S.J., and V.M. du Cann, 2007, Binderless briquetting of some selected South African prime coking, blend coking and weathered bituminous coals and the effect of coal properties on binderless briquetting: International Journal of Coal Geology, v. 71, p. 303-312.Mangena, S.J., and V.M. du Cann, 2007, Binderless briquetting of some selected South African prime coking, blend coking and weathered bituminous coals and the effect of coal properties on binderless briquetting: International Journal of Coal Geology, v. 71, p. 303-312.Mangena, S.J., and V.M. du Cann, 2007, Binderless briquetting of some selected South African prime coking, blend coking and weathered bituminous coals and the effect of coal properties on binderless briquetting: International Journal of Coal Geology, v. 71, p. 303-312.Mani, D., D.J. Patil, A.M. Dayal, S. Kavitha, M. Hafiz, N. Hakhoo, and G.M. Bhat, 2014, Gas potential of Proterozoic and Phanerozoic shales from the NW Himalaya, India: Inferences from pyrolysis: International Journal of Coal Geology, v. 128-129, p. 81-95.Mankiewicz, P.J., R.J. Pottorf, M.G. Kozar, and P. Vrolijk, 2009, Gas geochemistry of the Mobile Bay Jurassic Norphlet Formation: Thermal controls and implications for reservoir connectivity: AAPG Bulletin, v. 93, p. 1319-1346.Manovic, V., and P. Fennell, eds., 2014, Fluidized bed combustion and gasification—CO2 and SO2 capture: Fuel, v. 127, 228 p.Manz, O.E., 1998, Coal fly ash: a retrospective and future look: Energeia, v. 9, no. 2, p. 1,2,5.

Marchioni, D. L., 1980, Petrography and depositional environment of the Liddell seam, Upper Hunter Valley, New South Wales: International Journal of Coal Petrology, v. 1, p. 35-61.Marchioni, D. L., 1980, Petrography and depositional environment of the Liddell seam, Upper Hunter Valley, New South Wales: International Journal of Coal Petrology, v. 1, p. 35-61.Marchioni, D., and W. Kalkreuth, 1991, Coal facies interpretations based on lithotype and maceral variations in Lower Cretaceous (Gates Formation) coals of western Canada: International Journal of Coal Geology, v. 18, p. 125-162.Marchioni, D., and W. Kalkreuth, 1991, Coal facies interpretations based on lithotype and maceral variations in Lower Cretaceous (Gates Formation) coals of western Canada: International Journal of Coal Geology, v. 18, p. 125-162.Marchioni, D., M. Gibling, and W. Kalkreuth, 1996, Petrography and depositional environment of coal seams in the Carboniferous Morien Group, Sydney coalfield, Nova Scotia: Canadian Journal of Earth Sciences, v. 33, p. 863-874.Marchioni, D., W. Kalkreuth, J. Utting, and M. Fowler, 1994, Petrographical, palynological and geochemical analyses of the Hub and Harbour seams, Sydney coalfield, Nova Scotia, Canada—implications for facies development: Palaeogeography, Palaeoclimatology, Palaeoecology, v. 106, p. 241-270.Marchioni, D., W. Kalkreuth, J. Utting, and M. Fowler, 1994, Petrographical, palynological and geochemical analyses of the Hub and Harbour seams, Sydney Coalfield, Nova Scotia; implications for facies development: Palaeogeography, Palaeoclimatology, Palaeoecology, v. 106, p. 241-270.Marchioni, D.L., 1978, The effect on vitrinite reflectance of elevated temperatures during sample preparation: Geological Survey of Canada Paper 78-1C, p. 125-126.Marchioni, D.L., 1978, The effect on vitrinite reflectance of elevated temperatures during sample preparation: Geological Survey of Canada, Paper 78-1C, p. 125-126.Marchioni, D.L., 1983, The detection of weathering in coal by petrographic, rheologic and chemical methods: International Journal of Coal Geology, v. 2, p. 231-259.Marchioni, D.L., 1985, Reflectance studies in brown coals: an example from the Hat Creek deposit of British Columbia: Compte Rendu Neuvieme Congres International de Stratigraphie ed de Geologie du Carbonifere, v. 4, p. 590-599.Mardon, S.M., and J.C. Hower, 2004, Impact of coal properties on coal combustion by-product quality: examples from a Kentucky power plant: International Journal of Coal Geology, v. 59, p. 153-169.Mardon, S.M., C.F. Eble, J.C. Hower, K. Takacs, M. Mastalerz, and R.M. Bustin, 2014, Organic petrology, geochemistry, gas content and gas composition of Middle Pennsylvanian age coal beds in the Eastern Interior (Illinois) Basin: Implications for CBM development and carbon sequestration: International Journal of Coal Geology, v. 127, p. 56-74.Mardon, S.M., C.F. Eble, J.C. Hower, K. Takacs, M. Mastalerz, and R.M. Bustin, 2014, Organic petrology, geochemistry, gas content and gas composition of Middle Pennsylvanian age coal beds in the Eastern Interior (Illinois) Basin: Implications for CBM development and carbon sequestration: International Journal of Coal Geology, v. 127, p. 56-74.Mardon, S.M., J.C. Hower, J.M.K. O’Keefe, M.N. Marks, and D.H. Hedges, 2008, Coal combustion by-product quality at two stoker boilers: Coal source vs. fly ash collection system design: International Journal of Coal Geology, v. 75, p. 248-254.Mares, T.E., A.P. Radliński, T.A. Moore, D. Cookson, P. Thiyagarajan, J. Ilavsky, and J. Klepp, 2009, Assessing the potential for CO2 adsorption in a subbituminous coal, Huntly coalfield, New Zealand, using small angle scattering techniques: International Journal of Coal Geology, v. 77, p. 54-68.Mares, T.E., A.P. Radliński, T.A. Moore, D. Cookson, P. Thiyagarajan, J. Ilavsky, and J. Klepp, 2012, Location and distribution of inorganic material in a low ash yield, subbituminous coal: International Journal of Coal Geology, v. 94, p. 173-181.Mares, T.E., and T.A. Moore, 2008, The influence of macroscopic texture on biogenically-derived coalbed methane, Huntly coalfield, New Zealand: International Journal of Coal Geology, v. 76, p. 175-185.Mares, T.E., T.A. Moore, and C.R. Moore, 2009, Uncertainty of gas saturation estimates in a subbituminous coal seam: International Journal of Coal Geology, v. 77, p. 320-327.Marikos, M.A., R.C. Laudon, and J.S. Leventhal, 1986, Solid insoluble bitumen in the Magmont West orebody, southeast Missouri: Economic Geology, v. 81, p. 1983-1988.Marini, L., 2007, Geological sequestration of carbon dioxide: Thermodynamics, kinetics, and reaction path modeling: New York, Elsevier, Developments in Geochemistry 11, 453 p.Markovic, V., and H. Marsh, 1983, Microscopic techniques to examine structure in anisotropic cokes: Journal of Microscopy, v. 132, pt. 3, p. 345-352.Markowski, A.K., 1993, Coalbed methane: new energy from an old scourge: Pennsylvania Geological Survey, Pennsylvania Geology, v. 24, no. 2, p. 8-14.

Manzanares, P.L., E.S. Garbett, D.A. Spears, M. Widdowson, and G. Richards, 1995, Ignition of coal particles, in J.A. Pajares and J.M.D. Tascon, eds., Coal science: New York, Elsevier, Coal Science and Technology 24, v. 1, p. 587-590.

Markowski, A.K., 1995, Reconnaissance of gas contents and geologic aspects of the coalbed methane resources of Pennsylvania: Pennsylvania Geological Survey, 4 th ser., Open-File Report 95-09, p. 125-140.Markowski, A.K., 1998, Coalbed methane resource potential and current prospects in Pennsylvania, in P.C. Lyons, ed., Special issue: Appalachian coalbed methane: International Journal of Coal Geology, v. 38, p. 137-159.Markowski, A.K., 2000, Pennsylvania coalbed methane wells spreadsheet: Pennsylvania Geological Survey, 4 th ser., Open-File Report 00-01, 580 p.Markowski, A.K., 2001, Reconnaissance of the coal-bed methane resources in Pennsylvania: Pennsylvania Geological Survey, 4 th ser., Mineral Resource Report 95, 134 p.

Markowski, A.K., and J.A. Harper, 1998, Geological aspects of coalbed methane in the northern Appalachian coal basin, southwestern Pennsylvania and north-central West Virginia: Pennsylvania Bureau of Topographic and Geologic Survey, Open-File Report 98-13, 72 p.

Maroto-Valer, M.M., D.N. Taulbee, and J.C. Hower, 1999, Novel separation of the differing forms of unburned carbon present in fly ash using density gradient centrifugation: Energy & Fuels, v. 13, p. 947-953.Maroto-Valer, M.M., D.N. Taulbee, and J.C. Hower, 2001, Characterization of differing forms of unburned carbon present in fly ash separated by density gradient centrifugation: Fuel, v. 80, p. 795-800.

Maroto-Valer, M.M., D.N. Taulbee, J.M. Andresen, J.C. Hower, and C.E. Snape, 1998, The role of semifusinite in plasticity development for a coking coal: Energy & Fuels, v. 12, p. 1040-1046.

Marroquin, I.D., and B.S. Hart, 2004, Seismic attribute-based characterization of coalbed methane reservoirs: an example from the Fruitland Formation, San Juan Basin, New Mexico: AAPG Bulletin, v. 88, p. 1603-1621.

Marsh, H., 1973, Carbonization and liquid-crystal (mesophase) development: part 1. The significance of the mesophase during carbonization of coking coals: Fuel, v. 52, p. 205-211.Marsh, H., 1982, Coal carbonization—formation, properties and relevance of microstructures in resultant cokes: Iron and Steel Society Conference Proceedings, v. 41, p. 2-11.Marsh, H., and D.E. Clarke, 1986, Mechanisms of formation of structure within metallurgical coke and its effect on coke properties: Erdöl und Kohle-Erdgas-Petrochemie, v. 39, no. 3, p. 113-122.

Marsh, H., ed., 1989, Introduction to carbon science: Boston, Butterworths, 321 p.Marsh, H., H.W. Akitt, J.M. Hurley, J. Melvin, and P. Warburton, 1971, Formation of graphitisable carbons from gilsonite pitch and polyvinyl chloride — a mass spectrometric and NMR study: Journal of Applied Chem. Biotechnology, v. 21, p. 251-260.Marshall, C.E., 1942, Modern conceptions of the physical constitution of coal and related research in Great Britain: Journal of Geology, v. 50, p. 385-405.Marshall, C.E., 1954, Introduction to a study of the nature and origin of fusain (fusinite): Fuel, v. 33, p. 134-144.Marshall, C.E., 1955, Coal petrology: Economic Geology, Fiftieth Anniversary Volume, Part 2, p. 757-834.

Marshall, C.E., and J.A. Harrison, 1956, Influence of "fusain" blends upon coke character of Illinois coals: Illinois State Geological Survey Reprint 1962-Q.

Marshall, J.E.A., 1991, Quantitative spore colour: Journal of the Geological Society, London, v. 148, part 2, p. 223-233.Marshall, J.E.A., 1995, The Silurian of Saudi Arabia: thermal maturity, burial history and geotectonic environment: Review of Palaeobotany and Palynology, v. 89, p. 139-150.Marshall, J.E.A., P.D.W. Haughton, and S.J. Hillier, 1994, Vitrinite reflectivity and the structure and burial history of the Old Red Sandstone of the Midland Valley of Scotland: Journal of the Geological Society of London, v. 151, pt. 3, p. 425-438.Marshall, R.J., 1976, Classification of coking coals: Fuel, v. 55, p. 346-348.

Martinec, P., J. Jirásek, A. Kožušníková, and M. Sivek, eds., 2005, Atlas of coal: The Czech part of the Upper Silesian Basin, Anagram, Ostrava, 31 p., CD-ROM.Martinez, L., P. Bertrand, B. Pradier, and E. Lemaire, 1988, Localization of oil in microstructures of source rocks. application of a microspectrofluorimetric method: Organic Geochemistry, v. 13, p. 1093-1100.Martinez, M., and M. Escobar, 1995, Effect of coal weathering on some geochemical parameters: Organic Geochemistry, v. 23, p. 253-261.Martinez-Alonso, A., M.R. Martinez-Tarazona, and J.M.D. Tascon, 1992, Mineral matter in Spanish bituminous and brown coals, part 1. Development of methodology and identification of inorganic constituents: Erdol und Kohle-Erdgas-Petrochemie, v. 45, no. 3, p. 121-128.Martinez-Tarazona, M.R., A. Martinez-Alonso, and J.M.D. Tascon, 1993, Mineral matter in Spanish bituminous and brown coals, part 2. Mineral matter quantification: Erdol und Kohle-Erdgas-Petrochemie, v. 46, no. 5, p. 202-209.Martinez-Tarazona, M.R., and J.M. Cardin, 1990, Chlorine in Asturian coals: Journal of Coal Quality, v. 9, p. 66-70.Martinez-Tarazona, M.R., J.M. Palacios, and J.M. Cardin, 1988, The mode of occurrence of chlorine in high volatile bituminous coals from the Asturian central coalfield: Fuel, v. 67, p. 1624-1628.Martini, A.M., K. Nüsslein, and S.T. Petsch, 2005, Enhancing microbial gas from unconventional reservoirs: GasTIPS, v. 11, no. 2, p. 3-7.

Markowski, A.K., 2004, Coal-bed methane—Energy within reach: Pennsylvania Geological Survey, Pennsylvania Geology, v. 34, no. 1, p. 2-9. http://www.dcnr.state.pa.us/cs/groups/public/documents/document/dcnr_006834.pdf Markowski, A.K., 2005, Energy bills getting you down? Maybe coal and unconventional energy sources can help: Pennsylvania Geological Survey, Pennsylvania Geology, v. 35, no. 2, p. 2-9. http://www.dcnr.state.pa.us/cs/groups/public/documents/document/dcnr_006839.pdf Markowski, A.K., 2014, The state of Pennsylvania’s coalbed methane resources: Pennsylvania Geological Survey, Pennsylvania Geology, v. 44, no. 1, p. 12-13. http://www.dcnr.state.pa.us/cs/groups/public/documents/document/dcnr_20029447.pdf

Markowski, A.K., compiler, 2011, Pennsylvania coalbed methane wells database: Pennsylvania Geological Survey, 4th ser., Open-File Report OFOG 11–01.0, Microsoft Access database. http://www.dcnr.state.pa.us/topogeo/cbm/ofreport1101.aspx

Maroto-Valer, M.M., D.N. Taulbee, J.M. Andresen, J.C. Hower, and C.E. Shape, 1998, Quantitative 13C NMR study of structural variations within the vitrinite and inertinite maceral groups for a semifusinite-rich bituminous coal: Fuel, v. 77, p. 805-813.

Marquis, F., E. Lafargue, and J. Espitalie, 1992, The influence of maceral composition and maturity on the petroleum-generating potential of coals, in A.M. Spencer, ed., Generation, accumulation, and production of Europe's hydrocarbons II: New York, Springer-Verlag, Special Publication 2 of the European Association of Petroleum Geoscientists, p. 239-247.

Marschner, R.F., and J.C. Winters, 1976, Differences among ozokerites, in T.F. Yen, ed., Shale oil, tar sands, and related fuel sources: Advances in chemistry series 151, p. 166-178.

Marsh, H., and J. Smith, 1978, The formation and properties of anisotropic cokes from coals and coal derivatives studied by optical and scanning electron microscopy, in C. Karr, Jr., ed., Analytical methods for coal and coal products, part 2: New York, Academic Press, p. 371-414.Marsh, H., and R. Menendez, 1989, Mechanisms of formation of isotropic and anisotropic carbons, in H. Marsh, ed., Introduction to carbon science: Boston, Butterworths, p. 37-73.

Marshall, C.E., and J.A. Harrison, 1956, Influence of "fusain" blends upon coke character of Illinois coals, in Third conference on the origin and constitution of coal: Nova Scotia Department of Mines, p. 212-226.

Marshall, J.E.A., 1990, Determination of thermal maturity, in D.E.G. Briggs and P.R. Crowther, eds., Palaeobiology, a synthesis: Boston, Blackwell Scientific Publications, p. 511-515.

Martin, J.W., and V.V. Cararoc, 1991, Lithotype control of trace element concentrations in some southeastern West Virginia coals, in D.C. Peters, ed., Geology in coal resource utilization: Fairfax, VA, Techbooks, p. 427-450 (available from AAPG)Martinec, P., J. Honek, and F. Stanek, 2002, Bituminous coal of the Upper Silesian Basin, the Czech Republic—relationship between mean vitrinite reflectance Ro, volatile matter Vdaf, and content of carbon, hydrogen and nitrogen, in L.V. Hills, C.M. Henderson, and E.W. Bamber, eds., Carboniferous and Permian of the World: Canadian Society of Petroleum Geologists Memoir 19, p. 902-909.Martinec, P., J. Honek, and F. Stanek, 2002, Bituminous coal of the Upper Silesian Basin, the Czech Republic—relationship between mean vitrinite reflectance Ro, volatile matter Vdaf, and content of carbon, hydrogen and nitrogen, in L.V. Hills, C.M. Henderson, and E.W. Bamber, eds., Carboniferous and Permian of the World: Canadian Society of Petroleum Geologists Memoir 19, p. 902-909.

Martino, R.L., 2004, Sequence stratigraphy of the Glenshaw Formation (Middle–Late Pennsylvanian) in the Central Appalachian Basin, in J.C. Pashin and R.A. Gastaldo, eds., Sequence stratigraphy, paleoclimate, and tectonics of coal-bearing strata: AAPG Studies in Geology 51, p. 1-28.

Martins, M.F., S. Salvador, J.-F. Thovert, and G. Debenest, 2009, Co-current combustion of oil shale–Part 1: Characterization of the solid and gaseous products: Fuel, v. 89, p. 144-151.Martins, M.F., S. Salvador, J.-F. Thovert, and G. Debenest, 2009, Co-current combustion of oil shale–Part 2: Structure of the combustion front: Fuel, v. 89, p. 133-143.Marynowski, L., A. Gaweda, P. Poprawa, M.M. Zywiecki, B. Kepinska, and H. Merta, 2006, Origin of organic matter from tectonic zones in the Western Tatra Mountains crystalline basement, Poland: an example of bitumen–source rock correlation: Marine and Petroleum Geology, v. 23, p. 261-279.Marynowski, L., and M. Zatoń, 2010, Organic matter from the Callovian (Middle Jurassic) deposits of Lithuania: Compositions, sources and depositional environments: Applied Geochemistry, v. 25, p. 933-946.Marynowski, L., and P. Wyszomirski, 2008, Organic geochemical evidences of early diagenetic oxidation of the terrestrial organic matter during the Triassic arid and semi arid climatic conditions: Applied Geochemistry, v. 23, p. 2612-2618.Marynowski, L., E. Szełęg, M.O. Jędrysek, and B.R.T. Simoneit, 2011, Effects of weathering on organic matter Part II: Fossil wood weathering and implications for organic geochemical and petrographic studies: Organic Geochemistry, v. 42, p. 1076-1088.Marynowski, L., S. Kurkiewicz, M. Rakociński, and B.R.T. Simoneit, 2011, Effects of weathering on organic matter: I. Changes in molecular composition of extractable organic compounds caused by paleoweathering of a Tournaisian marine black shale: Chemical Geology, v. 285, p. 144-156.

Masoudian, M.S., D.W. Airey, and A. El-Zein, 2014, Experimental investigations on the effect of CO2 on mechanics of coal: International Journal of Coal Geology, v. 128-129, p. 12-23.Masoudian, M.S., D.W. Airey, and A. El-Zein, 2014, Experimental investigations on the effect of CO2 on mechanics of coal: International Journal of Coal Geology, v. 128-129, p. 12-23.

Massarotto, P., S.D. Golding, J.-S. Bae, R. Iyer, and V. Rudolph, 2010, Changes in reservoir properties from injection of supercritical CO2 into coal seams — a laboratory study: International Journal of Coal Geology, v. 82, p. 269-279.Massey, L.G., ed., 1974, Coal gasification: Washington, D.C., American Chemical Society, Advances in Chemistry Series 131, 266 p.Massoud, M.S., A.C. Scott, S.D. Killops, D. Mattey, and M.L. Keeley, 1993, Oil source rock potential of the lacustrine Jurassic Sim Uuju Formation, west Korea Bay basin, part II: nature of the organic matter and hydrocarbon-generation history: Journal of Petroleum Geology, v. 16, p. 265-284.Massoud, M.S., A.C. Scott, S.D. Killops, D. Mattey, and M.L. Keeley, 1993, Oil source rock potential of the lacustrine Jurassic Sim Uuju Formation, west Korea Bay basin, part II: nature of the organic matter and hydrocarbon-generation history: Journal of Petroleum Geology, v. 16, p. 265-284.Massoud, M.S., A.C. Scott, S.D. Killops, D. Mattey, and M.L. Keeley, 1993, Oil source rock potential of the lacustrine Jurassic Sim Uuju Formation, west Korea Bay basin, part II: nature of the organic matter and hydrocarbon-generation history: Journal of Petroleum Geology, v. 16, p. 265-284.Massoud, M.S., and R.R.F. Kinghorn, 1985, A new classification for the organic components of kerogen: Journal of Petroleum Geology, v. 8, p. 85-100.

Mastalerz, M., A. Drobniak, and A. Schimmelmann, 2009, Changes in optical properties, chemistry, and micropore and mesopore characteristics of bituminous coal at the contact with dikes in the Illinois Basin: International Journal of Coal Geology, v. 77, p. 310-319.Mastalerz, M., A. Drobniak, and A. Schimmelmann, 2009, Changes in optical properties, chemistry, and micropore and mesopore characteristics of bituminous coal at the contact with dikes in the Illinois Basin: International Journal of Coal Geology, v. 77, p. 310-319.Mastalerz, M., A. Drobniak, and A. Schimmelmann, 2009, Changes in optical properties, chemistry, and micropore and mesopore characteristics of bituminous coal at the contact with dikes in the Illinois Basin: International Journal of Coal Geology, v. 77, p. 310-319.Mastalerz, M., A. Drobniak, and G. Filippelli, 2004, Distribution of mercury in Indiana coals and implications for mining and combustion: Indiana Geological Survey Open-File Study 04-04, CD-ROM.Mastalerz, M., A. Drobniak, and G. Filippelli, 2004, Distribution of mercury in Indiana coals and implications for mining and combustion: Indiana Geological Survey Open-File Study 04-04, CD-ROM.Mastalerz, M., A. Drobniak, and G. Filippelli, 2006, Mercury content and petrographic composition in Pennsylvanian coal beds of Indiana, USA: International Journal of Coal Geology, v. 68, p. 2-13.Mastalerz, M., A. Drobniak, and J. Rupp, 2008, Meso- and micropore characteristics of coal lithotypes: implications for CO2 adsorption: Energy and Fuels, v. 22, p. 4049-4061.Mastalerz, M., A. Drobniak, D. Strąpoć, W.S. Acosta, and J. Rupp, 2008, Variations in pore characteristics in high volatile bituminous coals: Implications for coal bed gas content: International Journal of Coal Geology, v. 76, p. 205-216.Mastalerz, M., A. Drobniak, R. Walker, and D. Morse, 2010, Coal lithotypes before and after saturation with CO2; insights from micro- and mesoporosity, fluidity, and functional group distribution: International Journal of Coal Geology, v. 83, p. 467-474.Mastalerz, M., A. Schimmelmann, J.C. Hower, G. Lis, J. Hatch, and S.R. Jacobson, 2003, Chemical and isotopic properties of kukersites from Iowa and Estonia: Organic Geochemistry, v. 34, p. 1419-1427.Mastalerz, M., A. Schimmelmann, J.C. Hower, G. Lis, J. Hatch, and S.R. Jacobson, 2003, Chemical and isotopic properties of kukersites from Iowa and Estonia: Organic Geochemistry, v. 34, p. 1419-1427.Mastalerz, M., and A. Drobniak, 2005, Optical properties of pseudovitrinite; implications for its origin: International Journal of Coal Geology, v. 62, p. 250-258.Mastalerz, M., and A. Drobniak, 2005, Vertical variations of mercury in Pennsylvanian coal beds from Indiana: International Journal of Coal Geology, v. 63, p. 36-57.Mastalerz, M., and A. Drobniak, 2007, Arsenic, cadmium, lead, and zinc in the Danville and Springfield coal members (Pennsylvanian) from Indiana: International Journal of Coal Geology, v. 71, p. 37-53.Mastalerz, M., and A. Drobniak, 2012, Gallium and germanium in selected Indiana coals: International Journal of Coal Geology, v. 94, p. 302-313.Mastalerz, M., and A. Drobniak, 2013, Variations in CO2 emissions from Pennsylvanian coals of the eastern part of the Illinois Basin: International Journal of Coal Geology, v. 108, p. 10-17.Mastalerz, M., and E.P. Kvale, 1998, Coal-bed gas potential in Daviess County, Indiana: Indiana Geological Survey, Open-File Study 98-7.Mastalerz, M., and E.P. Kvale, 2000, Coal quality variation and coalbed gas content in boreholes SDH-383 and SDH-384 in Posey County, Indiana: Indiana Geological Survey, Open-File Study 00-5, 30 p.Mastalerz, M., and J.C. Hower, 1996, Elemental composition and molecular structure of Botryococcus alginate in Westphalian cannel coals from Kentucky: Organic Geochemistry, v. 24, p. 301-308.Mastalerz, M., and J.C. Hower, 1996, Elemental composition and molecular structure of Botryococcus alginate in Westphalian cannel coals from Kentucky: Organic Geochemistry, v. 24, p. 301-308.

Mason, D.M., 1976, Control of agglomeration in coal hydrogasification, in C.J. Smith, compiler, Proceedings of the coal agglomeration and conversion symposium: West Virginia Geological and Economic Survey, p. 163-174.

Masran, T.C., and S.A.J. Pocock, 1981, The classification of plant-derived particulate organic matter in sedimentary rocks, in J. Brooks, ed., Organic maturation studies and fossil fuel exploration: San Francisco, Academic Press, p. 145-175.Massarotto, P., 1999, Cost benefit analysis of coalbed methane recovery activities in Australia and New Zealand — implications for commercial projects and government policy, in M. Mastalerz, M. Glikson, and S.D. Golding, eds., Coalbed methane: scientific, environmental and economic evaluation: Boston, Kluwer Academic Publishers, p. 33-54.

Masszi, D., 1991, Cavity stress-relief method for recovering methane from coal seams, in S.D. Schwochow, D.K. Murray, and M.F. Fahy, eds., Coalbed methane of western North America: Denver, Rocky Mountain Association of Geologists, p. 149-154. (new stimulation technique)Mastalerz, M., 1991, Variation of vitrinite reflectance in a vertical seam section. An example from the Intrasudetic basin, SW Poland, in P. Bertrand, ed., Coal: formation, occurrence and related properties: Bull. Soc. Geol. France, v. 162, p. 175-182.Mastalerz, M., 2014, Coal bed methane: reserves, production and future outlook, in T.M. Letcher, ed., Future energy, second edition: New York, Elsevier, p. 145-158.

Mastalerz, M., and L.W. Gurba, 2001, Determination of nitrogen in coal macerals using electron microprobe technique—experimental procedure: International Journal of Coal Geology, v. 47, p. 23-30.Mastalerz, M., and M. Glikson, 2000, In-situ analysis of solid bitumen in coal: examples from the Bowen basin and the Illinois basin: International Journal of Coal Geology, v. 42, p. 207-220. (uses the term "solid bitumen" for exudatinite)Mastalerz, M., and P.L. Padgett, 1999, From in situ coal to the final coal product: a case study of the Danville coal member (Indiana): International Journal of Coal Geology, v. 41, p. 107-123.Mastalerz, M., and R.M. Bustin, 1993, Electron microprobe and micro-FTIR analysis applied to maceral chemistry: International Journal of Coal Geology, v. 24, p. 333-345.Mastalerz, M., and R.M. Bustin, 1993, Electron microprobe and micro-FTIR analysis applied to maceral chemistry: International Journal of Coal Geology, v. 24, p. 333-345.Mastalerz, M., and R.M. Bustin, 1993, Variation in elemental composition of macerals; an example of the application of electron microprobe to coal studies: International Journal of Coal Geology, v. 22, p. 83-99.Mastalerz, M., and R.M. Bustin, 1993, Variation in elemental composition of macerals; an example of the application of electron microprobe to coal studies: International Journal of Coal Geology, v. 22, p. 83-99.Mastalerz, M., and R.M. Bustin, 1993, Variation in elemental composition of macerals; an example of the application of electron microprobe to coal studies: International Journal of Coal Geology, v. 22, p. 83-99.Mastalerz, M., and R.M. Bustin, 1993, Variation in maceral chemistry within and between coals of varying rank: an electron microprobe and micro-FTIR investigation: Journal of Microscopy, v. 171, p. 153-166.Mastalerz, M., and R.M. Bustin, 1993, Variation in maceral chemistry within and between coals of varying rank: an electron microprobe and micro-FTIR investigation: Journal of Microscopy, v. 171, Part 2, p. 153-166.Mastalerz, M., and R.M. Bustin, 1993, Variation in maceral chemistry within and between coals of varying rank: an electron microprobe and micro-FTIR investigation: Journal of Microscopy, v. 171, Part 2, p. 153-166.Mastalerz, M., and R.M. Bustin, 1994, Variation in reflectance and chemistry of vitrinite and vitrinite precursors in a series of Tertiary coals, Arctic Canada: Organic Geochemistry, v. 22, p. 921-933.Mastalerz, M., and R.M. Bustin, 1994, Variation in reflectance and chemistry of vitrinite and vitrinite precursors in a series of Tertiary coals, Arctic Canada: Organic Geochemistry, v. 22, p. 921-933.Mastalerz, M., and R.M. Bustin, 1994, Variation in reflectance and chemistry of vitrinite and vitrinite precursors in a series of Tertiary coals, Arctic Canada: Organic Geochemistry, v. 22, p. 921-933.Mastalerz, M., and R.M. Bustin, 1995, Application of reflectance micro-Fourier Transform Infrared spectrometry in studying coal macerals: comparison with other Fourier Transform Infrared techniques: Fuel, v. 74, p. 536-542.Mastalerz, M., and R.M. Bustin, 1996, Application of reflectance micro-FTIR in studying macerals; an example from the Late Jurassic to Early Cretaceous coals of the Mist Mountain Formation, British Columbia, Canada: International Journal of Coal Geology, v. 32, p. 55-67.Mastalerz, M., and R.M. Bustin, 1996, Application of reflectance micro-FTIR in studying macerals; an example from the Late Jurassic to Early Cretaceous coals of the Mist Mountain Formation, British Columbia, Canada: International Journal of Coal Geology, v. 32, p. 55-67.Mastalerz, M., and R.M. Bustin, 1997, Variation in chemistry of macerals in coals of the Mist Mountain Formation, Elk valley Coalfield, B.C., Canada: International Journal of Coal Geology, v. 33, p. 43-59.Mastalerz, M., and R.M. Bustin, 1997, Variation in chemistry of macerals in coals of the Mist Mountain Formation, Elk valley coalfield, B.C., Canada: International Journal of Coal Geology, v. 33, p. 43-59.Mastalerz, M., and R.M. Bustin, 1997, Variation in the chemistry of macerals in coals of the Mist Mountain Formation, Elk Valley coalfield, British Columbia, Canada: International Journal of Coal Geology, v. 33, p. 43-59.Mastalerz, M., H. Gluskoter, and J. Rupp, 2004, Carbon dioxide and methane sorption in high volatile bituminous coals from Indiana, USA: International Journal of Coal Geology, v. 60, p. 43-55.Mastalerz, M., H. Gluskoter, and J. Rupp, 2004, Carbon dioxide and methane sorption in high volatile bituminous coals from Indiana, USA: International Journal of Coal Geology, v. 60, p. 43-55.

Mastalerz, M., J.C. Hower, A. Drobniak, S.M. Mardon, and G. Lis, 2004, From in-situ coal to fly ash: a study of coal mines and power plants from Indiana: International Journal of Coal Geology, v. 59, p. 171-192.

Mastalerz, M., J.C. Hower, and A. Carmo, 1998, In-situ FTIR and flash pyrolysis/GC-MS characterization of Protosalvinia (Upper Devonian, Kentucky): implications for maceral classification: Organic Geochemistry, v. 28, p. 57-66.Mastalerz, M., J.C. Hower, and A. Carmo, 1998, In-situ FTIR and flash pyrolysis/GC-MS characterization of Protosalvinia (Upper Devonian, Kentucky): implications for maceral classification: Organic Geochemistry, v. 28, p. 57-66.Mastalerz, M., K.R. Wilks, and R.M. Bustin, 1993, Variation in vitrinite chemistry as a function of associated liptinite content; a microprobe and FT-i.r. investigation: Organic Geochemistry, v. 20, p. 555-562.Mastalerz, M., K.R. Wilks, and R.M. Bustin, 1993, Variation in vitrinite chemistry as a function of associated liptinite content; a microprobe and FT-i.r. investigation: Organic Geochemistry, v. 20, p. 555-562.Mastalerz, M., K.R. Wilks, and R.M. Bustin, 1993, Variation in vitrinite chemistry as a function of associated liptinite content; a microprobe and FT-i.r. investigation: Organic Geochemistry, v. 20, p. 555-562.Mastalerz, M., K.R. Wilks, and R.M. Bustin, 1993, Variation in vitrinite chemistry as a function of associated liptinite content; a microprobe and FTIR investigation: Organic Geochemistry, v. 20, p. 555-562.Mastalerz, M., K.R. Wilks, and R.M. Bustin, 1993, Variation in vitrinite chemistry as a function of associated liptinite content; a microprobe and FTIR investigation: Organic Geochemistry, v. 20, p. 555-562.Mastalerz, M., M.L. Thomson, A. Stankiewicz, R.M. Bustin, and A.J. Sinclair, 1994, A geochemical study of solid bitumen in an Eocene epithermal deposit: Owen Lake, British Columbia, Canada: Chemical Geology, v. 115, p. 249-262.Mastalerz, M., R.M. Bustin, and M.N. Lamberson, 1993, Variation in chemistry of vitrinite and semifusinite as a function of associated inertinite content: International Journal of Coal Geology, v. 22, p. 149-162.Mastalerz, M., R.M. Bustin, and M.N. Lamberson, 1993, Variation in chemistry of vitrinite and semifusinite as a function of associated inertinite content: International Journal of Coal Geology, v. 22, p. 149-162.Mastalerz, M., R.M. Bustin, and M.N. Lamberson, 1993, Variation in chemistry of vitrinite and semifusinite as a function of associated inertinite content: International Journal of Coal Geology, v. 22, p. 149-162.Mastalerz, M., R.M. Bustin, and M.N. Lamberson, 1993, Variation in chemistry of vitrinite and semifusinite as a function of associated inertinite content: International Journal of Coal Geology, v. 22, p. 149-162.Mastalerz, M., W. Solano-Acosta, A. Schimmelmann, and A. Drobniak, 2009, Effects of coal storage in air on physical and chemical properties of coal and on gas adsorption: International Journal of Coal Geology, v. 79, p. 167-174.Mastalerz, M., W. Solano-Acosta, A. Schimmelmann, and A. Drobniak, 2009, Effects of coal storage in air on physical and chemical properties of coal and on gas adsorption: International Journal of Coal Geology, v. 79, p. 167-174.Mastral, A.M., C. Mayoral, M.J. Perez-Surio, J. Rivera-Utrilla, and F.J. Maldonado, 1994, Textural changes in cokemaking: Journal of Coal Quality, v. 13, no. 2, p. 43-45.

Mastalerz, M., J. Rupp, A. Drobniak, S. Harpalani, A. Anderson, K. Korose, S. Frailey, and D. Morse, 2009, Assessment of CO2 sequestration and enhanced coalbed methane potential in unminable coal seams of the Illinois Basin, in M. Grobe, J.C. Pashin, and R.L. Dodge, eds., Carbon dioxide sequestration in geological media–state of the art: AAPG Studies in Geology 59, p. 149-171.

Mastalerz, M., J.C. Hower, and A. Carmo, 1998, In situ FTIR and flash pyrolysis/GC-MS characterization of Protosalvinia (Upper Devonian, Kentucky, USA): implications for maceral classification: Organic Geochemistry, v. 28, p. 57-66.

Matchette-Downes, C.J., A.E. Fallick, Karmajaya, and S. Rowland, 1994, A maturity and palaeoenvironmental assessment of condensates and oils from the north Sumatra basin, Indonesia, in A.C. Scott and A.J. Fleet, eds., Coal and coal-bearing strata as oil-prone source rocks?: London, The Geological Society Special Publication 77, p. 139-148.

Mathews, J.P., and A.L. Chaffee, 2012, The molecular representations of coal—a review: Fuel, v. 96, p. 1-14.Mathews, W.H., and R.M. Bustin, 1984, Changes associated with natural in situ weathering of a coking coal from southeastern British Columbia: Fuel, v. 63, p. 548-550.

Matveyev, A.K., 1974, Oil shales outside the Soviet Union: Boston, G.K. Hall & Co., Deposits of fossil fuels, v. 4, 120 p.Mavor, M., and C.R. Nelson, 1997, Coalbed reservoir gas-in-place analysis: Gas Research Institute, 148 p.Mavor, M., T. Pratt, and R. DeBruyn, 1999, Study quantifies Powder River coal seam properties: Oil & Gas Journal, v. 97, no. 17, p. 35-40.Mavor, M.J., and J.C. Close, 1992, Formation evaluation of coalbed methane wells: GRI, Topical Report GRI 91-0334, 36 p.Mavor, M.J., and T.L. Logan, 1994, Recent advances in coal gas-well openhole well completion technology: Journal of Petroleum Technology, v. 46, p. 587-593.

Mavor, M.J., J.R. Robinson, W.D. Gunter, D.H.S. Law, and J. Gale, 2002, Testing for CO2 sequestration and enhanced methane production from coal: SPE Gas Technology Symposium Proceedings, SPE-75683, 14p.Mavor, M.J., L.B. Owen, and T.J. Pratt, 1992, Measurement and analysis of sorption isotherm data: GRI, Topical Report GRI 91-0335, 25 p.

Mavor, M.J., T.J. Pratt, and C.R. Nelson, 1995, Quantify the accuracy of coal seam gas content: Petroleum Engineer International, v. 68, no. 10, p. 37-42.May, M.T., and K.W. Kuehn, 2009, Renewed interest in heavy oils and rock asphalt in south central Kentucky: World Oil, v. 230, no. 8, p. 65-69.Maynard, J.B., E.R. Elswick, and J.C. Hower, 2001, Reflectance of dispersed vitrinite in shales hosting Pb-Zn-Cu ore deposits in western Cuba: comparison with clay crystallinity: International Journal of Coal Geology, v. 47, p. 161-170.Mazumber, S., M. Scott, and J. Jiang, 2012, Permeability increase in Bowen Basin coal as a result of matrix shrinkage during primary depletion: International Journal of Coal Geology, v. 96-97, p. 109-119.Mazumdar, M., P.S. Jacobsen, R.P. Killmeyer, and R.E. Hucko, 1992, Statistical analysis of an interlaboratory coal float-sink data set: Journal of Coal Quality, v. 11, p. 20-31.Mazumdar, M., R.W. Carlton, and G.A. Irdi, 1988, Statistical relationship between pyrite grain size distribution and pyritic sulfur reduction in Ohio coal: International Journal of Coal Geology, v. 9, p. 371-383.Mazumder, S., and K.H. Wolf, 2008, Differential swelling and permeability change of coal in response to CO2 injection for ECBM: International Journal of Coal Geology, v. 74, p. 123-138.Mazumder, S., and K.H. Wolf, 2008, Differential swelling and permeability change of coal in response to CO2 injection for ECBM: International Journal of Coal Geology, v. 74, p. 123-138.Mazumder, S., K.-H.A.A. Wolf, K. Elewaut, and R. Ephraim, 2006, Application of X-ray computed tomography for analyzing cleat spacing and cleat aperture in coal samples: International Journal of Coal Geology, v. 68, p. 205-222.Mazumder, S., P. van Hemert, A. Busch, K.-H.A.A. Wolf, and P. Tejera-Cuesta, 2006, Flue gas and pure CO2 sorption properties of coal: a comparative study: International Journal of Coal Geology, v. 67, p. 267-279.Mazumder, S., P. van Hemert, A. Busch, K.-H.A.A. Wolf, and P. Tejera-Cuesta, 2006, Flue gas and pure CO2 sorption properties of coal: a comparative study: International Journal of Coal Geology, v. 67, p. 267-279.Mazurek, M., A.J. Hurford, and W. Leu, 2006, Unravelling the multi-stage burial history of the Swiss Molasse Basin: integration of apatite fission track, vitrinite reflectance and biomarker isomerisation analysis: Basin Research, v. 18, p. 27-50.McAuliffe, C.D., 1979, Oil and gas migration: chemical and physical constraints: AAPG Bulletin, v. 63, p. 761-781.McCabe, C., R. Sassen, and B. Saffer, 1987, Occurrence of secondary magnetite within biodegraded oil: Geology, v. 15, p. 7-10.McCabe, L.C., 1942, Practical significance of the physical constitution of coal in coal preparation: Journal of Geology, v. 50, p. 406-410.

McCabe, P.J., 1991, Tectonic controls on coal accumulation: Bulletin de la Société Géologique de France, v. 162, p. 277-282.

McCabe, P.J., and J.T. Parrish, eds., 1992, Controls on the distribution and quality of Cretaceous coals: Geological Society of America Special Paper 267, 417 p.McCabe, P.J., and J.T. Parrish, eds., 1992, Controls on the distribution and quality of Cretaceous coals: Geological Society of America Special Paper 267, 417 p.McCabe, P.J., and K.W. Shanley, 1992, Organic control on shoreface stacking patterns: bogged down in the mire: Geology, v. 20, p. 741-744.McCabe, P.J., D.L. Gautier, M.D. Lewan, and C. Turner, 1993, The future of energy gases: USGS Circular 1115, 58 p.

Matsuoka, H., 1975, Requirements for coals in Japanese coking blends, in A.C. Cook, ed., Australian black coal: Australian Institute of Mining and Metallurgy, Illawarra Branch, p. 251-263.Matthews, C.B., 2005, Horizontal drilling the Lower Hartshorne coal, Arkoma Basin, Oklahoma: techniques and results, in B.J. Cardott, ed., Unconventional energy resources in the southern Midcontinent, 2004 symposium: Oklahoma Geological Survey Circular 110, p. 117-122.Matthews, R.D., 1983, The Devonian-Mississippian oil shale resource of the United States, in J.H. Gary, ed., Sixteenth Oil Shale Symposium Proceedings: Golden, Colorado School of Mines Press, p. 14-25.

Mavor, M.J., J.C. Close, and R.A. McBane, 1992, Formation evaluation of exploration coalbed methane wells, in Coalbed methane: Richardson, Texas, Society of Petroleum Engineers, SPE Reprint Series 35, p. 27-45.Mavor, M.J., J.C. Close, and R.A. McBane, 1992, Formation evaluation of exploration coalbed methane wells, in Coalbed methane: Society of Petroleum Engineers, Reprint Series 35, p. 27-45.

Mavor, M.J., R. Dhir, J.D. McLennan, and J.C. Close, 1991, Evaluation of hydraulic fracture stimulation of the Colorado 32-7 well, San Juan basin, in S.D. Schwochow, ed., Coalbed methane of western North America: Rocky Mountain Association of Geologists, p. 241-248.

McCabe, P. J., 1987, Facies studies of coal and coal-bearing strata, in A.C. Scott, ed., Coal and coal-bearing strata: recent advances: Geological Society Special Publication 32, p.51-66.McCabe, P.J., 1984, Depositional environments of coal and coal-bearing strata, in R.A. Rahmani and R.M. Flores, eds., Sedimentology of coal and coal-bearing sequences: Boston, Blackwell Scientific Publications, International Association of Sedimentologists Special Publication 7, p. 13-42.McCabe, P.J., 1984, Depositional environments of coal and coal-bearing strata, in R.A. Rahmani and R.M. Flores, eds., Sedimentology of coal and coal-bearing sequences: Boston, Blackwell Scientific Publications, International Association of Sedimentologists Special Publication 7, p. 13-42.McCabe, P.J., 1987, Facies studies of coal and coal-bearing strata, in A.C. Scott, ed., Coal and coal-bearing strata: recent advances: Geological Society Special Publication 32, p. 51-66.McCabe, P.J., 1991, Geology of coal; environments of deposition, in H.J. Gluskoter, D.D. Rice, and R.B. Taylor, eds., Economic geology, U.S.: Geological Society of America, The geology of North America, v. P-2, p. 469-482.

McCabe, P.J., and J.T. Parrish, 1992, Tectonic and climatic controls on the distribution and quality of Cretaceous coals, in P.J. McCabe and J.T. Parrish, eds., Controls on the distribution and quality of Cretaceous coals: Geological Society of America Special Paper 267, p. 1-15.

McCarthy, K., K. Rojas, M. Niemann, D. Palmowski, K. Peters, and A. Stankiewicz, 2011, Basic petroleum geochemistry for source rock evaluation: Oilfield Review, v. 23, no. 2, p. 32-43.McCartney, J.T., 1952, A study of the Seyler theory of coal reflectance: Economic Geology, v. 47, p. 202-210.McCartney, J.T., 1970, The granular micrinite component of coal: Fuel, v.49, p. 409-414.McCartney, J.T., and L.J.E. Hofer, 1955, Microreflectivity analysis of coal: Analytical Chemistry, v. 27, p. 1320-1325.McCartney, J.T., and M. Teichmuller, 1972, Classification of coals according to degree of coalfication by reflectance of the vitrinite component: Fuel, v. 51, p. 64-68.McCartney, J.T., and M. Teichmüller, 1972, Classification of coals according to degree of coalification by reflectance of the vitrinite component: Fuel, v. 51, p. 64-68.McCartney, J.T., and S. Ergun, 1967, Optical properties of coals and graphite: U.S. Bureau of Mines Bulletin 641, 49 p.

McConville, L.B., 1975, The Athabasca tar sands: Society of Mining Engineers, Mining Engineering, v. , p. 19-34.

McCormack, N., G. Clayton, and P. Fernandes, 2007, The thermal history of the Upper Palaeozoic rocks of southern Portugal: Marine and Petroleum Geology, v. 24, p. 145-150.McCulloch, C.M., and M. Deul, 1973, Geologic factors causing roof instability and methane emission problems: the Lower Kittanning coalbed, Cambria County, Pa.: U.S. Bureau of Mines Report of Investigations 7769, 25 p.

McCulloch, C.M., J.R. Levine, F.N. Kissell, and M. Deul, 1975, Measuring the methane content of bituminous coalbeds: U.S. Bureau of Mines Report of Investigations 8043, 22 p.McCulloch, C.M., M. Deul, and P.W. Jeran, 1974, Cleat in bituminous coalbeds: U.S. Bureau of Mines Report of Investigations 7910, 25 p.McCulloch, C.M., M. Deul, and P.W. Jeran, 1974, Cleat in bituminous coalbeds: U.S. Bureau of Mines Report of Investigations 7910, 25 p.McCulloch, C.M., S.W. Lambert, and J.R. White, 1976, Determining cleat orientation of deeper coalbeds from overlying coals: U.S. Bureau of Mines Report of Investigations 8116, 19 p.McCune, D., 2002, Fundamentals of coalbed methane production: Lawrence, University of Kansas, Tertiary Oil Recovery Project, 70 p.

McFarlane, R.A., T. Gentzis, F. Goodarzi, J.V. Hanna, and A.M. Vassallo, 1993, Evolution of the chemical structure of Hat Creek resinite during oxidation: a combined FT-IR photoacoustic, NMR and optical microscopic study: International Journal of Coal Geology, v. 22, p. 119-147.McHugh, E.A., C.F.K. Diessel, and R. Kutzner, 1991, Use of fluorescence microscopy in the detection of low level oxidation in bituminous coals: Fuel, v. 70, p. 647-653.McHugh, E.A., C.F.K. Diessel, and R. Kutzner, 1991, Use of fluorescence microscopy in the detection of low level oxidation in bituminous coals: Fuel, v. 70, p. 647-653.McIlvried, H.G., III, S.E. Plasynski, J.T. Litynski, D.M. Vikara, and R.D. Srivastava, 2011, The critical role of monitoring, verification, and accounting for geologic CO2 storage projects: Environmental Geosciences Journal, v. 18, no. 1.McIntosh, J., A. Martini, S. Petsch, R. Huang, and K. Nűsslein, 2008, Biogeochemistry of the Forest City Basin coalbed methane play: International Journal of Coal Geology, v. 76, p. 111-118.McIntyre, M. R., R. H. Groshong, Jr., and J. C. Pashin, 2003, Structure of Cedar Cove and Peterson coalbed methane fields and correlation to gas and water production: Tuscaloosa, Alabama, University of Alabama College of Continuing Studies, 2003 International Coalbed Methane Symposium Proceedings, Paper 0312, 14 p.McKee, B., 2003, CO2 capture and storage in geological formations: International Energy Agency (IEA), 14 p.

McKee, C.R., A.C. Bumb, S.C. Way, R.A. Koenig, J.M. Reverand, and D.F. Brandenburg, 1986, Using permeability-vs-depth correlations to assess the potential for producing gas from coal seams: Quarterly Review of Methane from Coal Seams Technology, v. 4, no. 1, p. 15-26.

McKee, E.D., E.J. Crosby, and others, 1975, Paleotectonic investigations of the Pennsylvanian System in the United States: U.S. Geological Survey Professional Paper 853, three parts.McKee, E.D., E.J. Crosby, and others, 1975, Paleotectonic investigations of the Pennsylvanian System in the United States; Part II. Interpretive summary and special features of the Pennsylvanian System: U.S. Geological Survey Professional Paper 853, 192 p.McKinnon, I., 2002, Canadian coalbed methane: Oil and Gas Investor, v. 22, no. 3, p. 56-59.McLaughlin, J.F., C.D. Frost, and S. Sharma, 2011, Geochemical analysis of Atlantic Rim water, Carbon County, Wyoming: new applications for characterizing coalbed natural gas reservoirs: AAPG Bulletin, v. 95, p. 191-217.McLaughlin, J.F., C.D. Frost, and S. Sharma, 2011, Geochemical analysis of Atlantic Rim water, Carbon County, Wyoming: new applications for characterizing coalbed natural gas reservoirs: AAPG Bulletin, v. 95, p. 191-217.McLennan, J.D., P.S. Schafer, and T.J. Pratt, 1995, A guide to determining coalbed gas content: Gas Research Institute, 181 p.McPherson, B.J., and E.T. Sundquist, 2009, Carbon sequestration and its role in the global carbon cycle: Washington, DC, American Geophysical Union, Geophysical Monograph 183, 359 p.McPhilemy, B., 1988, The value of fluorescence microscopy in routine palynofacies analysis: Lower Carboniferous successions from counties Armagh and Roscommon, Ireland: Review of Palaeobotany and Palynology, v. 56, p. 345-359.McPhilemy, B., 1988, The value of fluorescence microscopy in routine palynofacies analysis: Lower Carboniferous successions from counties Armagh and Roscommon, Ireland: Review of Palaeobotany and Palynology, v. 56, p. 345-359.

McCallister, T., 2000, Impact of unconventional gas technology in the annual energy outlook 2000: Energy Information Administration. http://www.eia.doe.gov/oiaf/analysispaper/unconventional_gas.html

McClanahan, E.A., 1995, Coalbed methane: myths, facts and legends of its history and the legislative and regulatory climate into the 21 st century: Oklahoma Law Review, v. 48, no. 3, p. 471-561.

McCord, J.P., 1984, Geologic overview, coal, and coalbed methane resources of the greater Green River coal region—Wyoming and Colorado, in C.T. Rightmire, G.E. Eddy, and J.N. Kirr, eds., Coalbed methane resources of the United States: AAPG Studies in Geology 17, p. 271-293.

McCulloch, C.M., and M. Deul, 1977, Methane from coal, in D.K. Murray, ed., Geology of Rocky Mountain coal, 1976 symposium: Colorado Geological Survey Resources Series 1, p. 121-136.McCulloch, C.M., and W.P. Diamond, 1979, Inexpensive method helps predict methane content of coal beds, in Planbook of coal mining: New York, McGraw-Hill, Inc., Coal Age, p. 76-80.

McCurdy, K.M., 2007, Congressional response to coal fires: illustrating transitions in the policy process, in G.B. Stracher, ed., Geology of coal fires: case studies from around the world: GSA Reviews in Engineering Geology 18, p. 271-278.McElhiney, J.E., G.W. Paul, G.B.C. Young, and J.A. McCartney, 1993, Reservoir engineering aspects of coalbed methane, in B.E. Law and D.D. Rice, eds., Hydrocarbons from coal: AAPG Studies in Geology 38, p. 361-372.

McKee, C.R., A.C. Bumb, and R.A. Koenig, 1988, Stress-dependent permeability and porosity of coal, in J.E. Fassett, ed., Geology and coal-bed methane resources of the northern San Juan basin, Colorado and New Mexico: Denver, Rocky Mountain Association of Geologists Guidebook, p. 143-153.

McKee, E.D., compiler, 1975, Interpretation of Pennsylvanian history, in E.D. McKee, E.J. Crosby, and others, Paleotectonic investigations of the Pennsylvanian System in the United States: U.S. Geological Survey Professional Paper 853, part II, p. 1-21.

McTavish, R.A., 1978, Pressure retardation of vitrinite diagenesis, offshore northwest Europe: Nature, v. 271, p. 648-650.McTavish, R.A., 1978, Pressure retardation of vitrinite diagenesis, offshore northwest Europe: Nature, v. 271, p. 648-650.McTavish, R.A., 1978, Pressure retardation of vitrinite diagenesis, offshore north-west Europe: Nature, v. 271, p. 648-650.McTavish, R.A., 1998, The role of overpressure in the retardation of organic matter maturation: Journal of Petroleum Geology, v. 21, p. 153-186.McTavish, R.A., 1998, The role of overpressure in the retardation of organic matter maturation: Journal of Petroleum Geology, v. 21, p. 153-186.

Medina, C.R., and J.A. Rupp, 2012, Reservoir characterization and lithostratigraphic division of the Mount Simon Sandstone (Cambrian): Implications for estimations of geologic sequestration storage capacity: Environmental Geosciences Journal, v. 19, no. 1.

Medina, J.C., S.J. Butala, C.H. Bartholomew, and M.L. Lee, 2000, Low temperature iron- and nickel-catalyzed reactions leading to coalbed gas formation: Geochimica et Cosmochimica Acta, v. 64, p. 643-649.Mehta, A., and R.B. Dooley, 1988, Proceedings: effects of coal quality on power plants: Palo Alto, CA, Electric Power Research Institute, various pages.Meij, R., and B.H. te Winkel, 2009, Trace elements in world steam coal and their behavior in Dutch coal-fired power stations: a review: International Journal of Coal Geology, v. 77, p. 289-293.

Mello, U.T., and G.D. Karner, 1996, Development of sediment overpressure and its effect on thermal maturation: application to the Gulf of Mexico basin: AAPG Bulletin, v. 80, p. 1367-1396.Mello, U.T., and G.D. Karner, 1996, Development of sediment overpressure and its effect on thermal maturation: application to the Gulf of Mexico basin: AAPG Bulletin, v. 80, p. 1367-1396.Melnichenko, Y.B., A.P. Radlinski, M. Mastalerz, G. Cheng, and J. Rupp, 2009, Characterization of the CO2 fluid adsorption n coal as a function of pressure using neutron scattering techniques (SANS and USANS): International Journal of Coal Geology, v. 77, p. 69-79.Melnichenko, Y.B., L. He, R. Sakurovs, A.L. Kholodenko, T. Blach, M. Mastalerz, A.P. Radliński, G. Cheng, and D.F.R. Mildner, 2011, Accessibility of pores in coal to methane and carbon dioxide: Fuel, v. 91, p. 200-208.Melnichenko, Y.B., L. He, R. Sakurovs, A.L. Kholodenko, T. Blach, M. Mastalerz, A.P. Radliński, G. Cheng, and D.F.R. Mildner, 2011, Accessibility of pores in coal to methane and carbon dioxide: Fuel, v. 91, p. 200-208.Melnichenko, Y.B., L. He, R. Sakurovs, A.L. Kholodenko, T. Blach, M. Mastalerz, A.P. Radliński, G. Cheng, and D.F.R. Mildner, 2011, Accessibility of pores in coal to methane and carbon dioxide: Fuel, v. 91, p. 200-208.Melzer, L.S., 2011, Emergence of residual zones, price and supply factors usher in new day in CO2 EOR: American Oil & Gas Reporter, v. 54, no. 2, p. 104-113.Melzer, L.S., 2012, Enhanced recovery projects constrained by shortage of carbon dioxide supplies: American Oil & Gas Reporter, v. 55, no. 2, p. 124-130.Mendonça Filho, J.G., 2010, Report on organic matter concentration working group (OMCWG 2009): ICCP News, no. 49, p. 15-28.Mendonça Filho, J.G., 2010, Report on organic matter concentration working group (OMCWG 2009): ICCP News, no. 49, p. 15-28.Mendonça Filho, J.G., 2013, Report on Organic Matter Concentration Working Group (OMCWG 2010): ICCP News, no. 57, p. 14-27.Mendonça Filho, J.G., 2013, Report on Organic Matter Concentration Working Group (OMCWG 2010): ICCP News, no. 57, p. 14-27.Mendonça Filho, J.G., 2013, Report on Organic Matter Concentration Working Group (OMCWG 2010): ICCP News, no. 57, p. 14-27.Mendonça Filho, J.G., C.V. Araujo, A.G. Borrego, A. Cook, D. Flores, P. Hackley, J.C. Hower, M.L. Kern, K. Kommeren, J. Kus, M. Mastalerz, J.O. Mendonça, T.R. Menezes, J. Newman, P. Ranasinghe, I.V.A.F. Souza, I. Suarez-Ruiz, and Y. Ujiié, 2010, Effect of concentration of dispersed organic matter on optical maturity parameters: Interlaboratory results of the organic matter concentration working group of the ICCP: International Journal of Coal Geology, v. 84, p. 154-165.Mendonça Filho, J.G., C.V. Araujo, A.G. Borrego, A. Cook, D. Flores, P. Hackley, J.C. Hower, M.L. Kern, K. Kommeren, J. Kus, M. Mastalerz, J.O. Mendonça, T.R. Menezes, J. Newman, P. Ranasinghe, I.V.A.F. Souza, I. Suarez-Ruiz, and Y. Ujiié, 2010, Effect of concentration of dispersed organic matter on optical maturity parameters: Interlaboratory results of the organic matter concentration working group of the ICCP: International Journal of Coal Geology, v. 84, p. 154-165.Mendonça Filho, J.G., C.V. Araujo, A.G. Borrego, A. Cook, D. Flores, P. Hackley, J.C. Hower, M.L. Kern, K. Kommeren, J. Kus, M. Mastalerz, J.O. Mendonça, T.R. Menezes, J. Newman, P. Ranasinghe, I.V.A.F. Souza, I. Suarez-Ruiz, and Y. Ujiié, 2011, Reply to effect of concentration of organic matter on optical maturity parameters. Interlaboratory results of the organic matter concentration working group of the ICCP. Discussion by Vinay K. Sahay: International Journal of Coal Geology, v. 86, p. 289-290.Mendonça Filho, J.G., M.G. Sommer, M.C. Klepzig, J.O. Mendonça, T.F. Silva, M.L. Kern, T.R. Menezes, A. Jasper, M.C. Silva, and L.G.C. Santos, 2013, Permian carbonaceous rocks from the Bonito coalfield, Santa Catarina, Brazil: Organic facies approaches: International Journal of Coal Geology, v. 111, p. 23-36.Mendonça Filho, J.G., M.G. Sommer, M.C. Klepzig, J.O. Mendonça, T.F. Silva, M.L. Kern, T.R. Menezes, A. Jasper, M.C. Silva, and L.G.C. Santos, 2013, Permian carbonaceous rocks from the Bonito coalfield, Santa Catarina, Brazil: Organic facies approaches: International Journal of Coal Geology, v. 111, p. 23-36.Mendonça Filho, J.G., R.B.A. Chagas, T.R. Menezes, J.O. Mendonça, F.S. da Silva, and E. Sabadini-Santos, 2010, Organic facies of the Oligocene lacustrine system in the Cenozoic Taubaté Basin, southern Brazil: International Journal of Coal Geology, v. 84, p. 166-178.

Merriam, D.F., ed., 1964, Symposium on cyclic sedimentation: Kansas Geological Survey Bulletin 169, v. 1, p. 1-380.Merriam, D.F., ed., 1964, Symposium on cyclic sedimentation: Kansas Geological Survey Bulletin 169, v. 2, p. 381-636.Merrick, D., 1984, Coal combustion and conversion technology: New York, Elsevier, 405 p.

McVay, D.A., R.O. Bello, W.B. Ayers, Jr., G.A. Hernandez, J.A. Rushing, S.K. Ruhl, M.F. Hoffmann, and R.I. Ramazanova, 2009, Evaluation of the technical and economic feasibility of CO2 sequestration and enhanced coalbed methane recovery in Texas low-rank coals, in M. Grobe, J.C. Pashin, and R.L. Dodge, edcs., Carbon dioxide sequestration in geological media—State of the science: AAPG Studies in Geology 59, p. 665-688.

Medina, J.C., S.J. Butala, C.H. Bartholomew, and M.L. Lee, 2000, Iron catalyzed CO2 hydrogenation as a mechanism for coalbed gas formation: Fuel, v. 79, p. 89-93.

Meissner, F.F., 1984, Cretaceous and lower Tertiary coals as source for gas accumulations in the Rocky Mountain area, in J. Woodward, F.F. Meissner, and J.L. Clayton, eds., Hydrocarbon source rocks of the Greater Rocky Mountain Region: Rocky Mountain Association of Geologists, p. 401-431.Meissner, F.F., 1987, Mechanisms and patterns of gas generation, storage expulsion-migration and accumulation associated with coal measures, Green River and San Juan basins, Rocky Mountain region, USA, in B. Doligez, ed., Migration of hydrocarbons in sedimentary basins: Paris, Editions Technip, Collection Colloques et Seminaires, v. 45, p. 79-112.

Menéndez, R., A. Gómez Borrego, J. Bailey, E. Fuente, and D. Alvarez, 1995, The effect of inertinite content on coal combustion reactivity, in J.A. Pajares and J.M.D. Tascon, eds., Coal science: New York, Elsevier, Coal Science and Technology 24, v. 1, p. 303-306.Mercier, T.J., 2011, Calculation of overburden above the LaClede bed of the Laney member of the Eocene Green River Formation, Green River and Washakie Basins, southwestern Wyoming: U.S. Geological Survey, Digital Data Series DDS-69-DD, chapter 4, 10 p. http://pubs.usgs.gov/dds/dds-069/dds-069-dd/REPORTS/69_DD_CH_4.pdfMercier, T.J., and R.C. Johnson, 2012, Isopach and isoresource maps for oil shale deposits in the Eocene Green River Formation for the combined Uinta and Piceance Basins, Utah and Colorado: U.S. Geological Survey Scientific Investigations Report 2012–5076, 85 p., 1 pl. http://pubs.usgs.gov/sir/2012/5076/ Mercier, T.J., G.L. Gunther, and C.C. Skinner, 2011, The GIS project for the geologic assessment of in-place oil shale resources of the Eocene Green River Formation, Greater Green River Basin, Wyoming, Colorado, and Utah: U.S. Geological Survey, Digital Data Series DDS-69-DD, chapter 3, 5 p. http://pubs.usgs.gov/dds/dds-069/dds-069-dd/REPORTS/69_DD_CH_3.pdfMercier, T.J., M.E. Brownfield, and R.C. Johnson, 2011, Methodology for calculating oil shale resources for the Green River and Washakie Basins, southwestern Wyoming: U.S. Geological Survey, Digital Data Series DDS-69-DD, chapter 2, 52 p. http://pubs.usgs.gov/dds/dds-069/dds-069-dd/REPORTS/69_DD_CH_2.pdfMercier, T.J., R.C. Johnson, M.E. Brownfield, and J.G. Self, 2010, In-place oil shale resources underlying federal lands in the Piceance Basin, western Colorado: U.S. Geological Survey, Fact Sheet 2010-3041, 4 p. http://pubs.usgs.gov/fs/2010/3041/

Merrick, D., 1984, Coal combustion and conversion technology: New York, Elsevier, 405 p.Merrill, R.K., ed., 1991, Source and migration processes and evaluation techniques: AAPG Treatise of Petroleum Geology, Handbook of Petroleum Geology, 213 p. (summary sheet, p. xvii)Merritt, R.D., 1986, Coal exploration, mine planning, and development: Park Ridge, New Jersey, Noyes Publications, 464 p.Merritt, R.D., 1988, General trends in major, minor, and trace elements in coal with a comparative profile of Alaskan coal: Journal of Coal Quality, v. 7, p. 95-103.

Mesroghli, S., E. Jorjani, and S.C. Chelgani, 2009, Estimation of gross calorific value based on coal analysis using regression and artificial neural networks: International Journal of Coal Geology, v. 79, p. 49-54.Messervey, J.P., and H.D. Smith, co-chairmen, 1950, Conference on the origin and constitution of coal: Crystal Cliffs, Nova Scotia Department of Mines, 159 p.Meszaros, G., P. Boonen, and M. Hale, 2007, New tools enable CBM horizontal drilling: Hart’s E&P, v. 80, no. 7, p. 60-61.

Meyer, R.F., and W. De Witt, Jr., 1990, Definition and world resources of natural bitumens: U.S. Geological Survey Bulletin 1944, 14 p.Meyers, R.A., 1981, Coal handbook: New York, Dekker, 854 p.Meyers, R.A., ed., 1982, Coal structure: New York, Academic Press, 340 p.Mi, J., S. Zhang, and K. He, 2014, Experimental investigations about the effect of pressure on gas generation from coal: Organic Geochemistry, v. 74, p. 116-122.Michael, K., and B.E. Buschkuehle, 2006, Acid-gas injection at West Stoddart, British Columbia: An analogue for the detailed hydrogeological characterization of a CO2 sequestration site: Journal of Geochemical Exploration, v. 89, p. 280-283.Michael, K., and S. Bachu, 2002, Coalbed methane producibility in the Cretaceous succession of the Alberta basin as affected by hydrogeology and stress regime (abstract): AAPG Annual Convention Official Program, v. 11, p. A121.

Michelsen, J.K., and G.K. Khorasani, 1990, Monitoring chemical alterations of individual oil-prone macerals by means of microscopical fluorescence spectrometry combined with multivariate data analysis: Organic Geochemistry, v. 15, p. 179-192.Michelsen, J.K., and G.K. Khorasani, 1994, The kinetics of thermal degradation of individual oil-generating macerals: calibration with microscopical fluorescence spectrometry and bulk flow pyrolysis: Organic Geochemistry, v. 22, p. 179-189.Middleton, M.F., 1982, Tectonic history from vitrinite reflectance: The Geophysical Journal of the Royal Astronomical Society, v. 68, p. 121-132.Middleton, M.F., 1990, Tectonic influence on vitrinite reflectance: International Journal of Coal Geology, v. 16, p. 235-237.Midgley, D.J., P. Hendry, K.L. Pinetown, D. Fuentes, S. Gong, D.L. Mitchell, and M. Faiz, 2010, Characterisation of a microbial community associated with a deep, coal seam methane reservoir in the Gippsland Basin, Australia: International Journal of Coal Geology, v. 82, p. 232-239.Mihaljevič, V. Ettler, L. Strnad, O. Šebek, F. Vonásek, P. Drahota, and J. Rohovec, 2009, Isotopic composition of lead in Czech coals: International Journal of Coal Geology, v. 78, p. 38-46.Miles, J.A., 1989, Illustrated glossary of petroleum geochemistry: Oxford, Clarendon Press, 137 p.

Milici, R.C., 2009, Coal-to-liquids: Potential impact on U.S. coal reserves: Natural Resources Research, v. 18, p. 85-94.Milici, R.C., J.R. Hatch, and M.J. Pawlewicz, 2010, Coalbed methane resources of the Appalachian Basin, eastern USA: International Journal of Coal Geology, v. 82, p. 160-174.Milici, R.C., R.M. Flores, and G.D. Stricker, 2013, Coal resources, reserves and peak coal production in the United States: International Journal of Coal Geology, v. 113, p. 109-115.

Millais, R., and D.G. Murchison, 1969, Properties of the coal macerals: infra-red spectra of alginates: Fuel, v. 48, p. 247-258.Miller, M., J. Platt, J. Price, R. Schadelbaur, and S. Suboleski, eds., 1993, New perspectives on central Appalachian low-sulfur coal supplies: Fairfax, VA, Tech Books.Miller, M.S., and M. Moore, 1980, Geophysical logging and exploration techniques in the Appalachian coal fields: Society of Petroleum Engineers of AIME, SPE 9466, 10 p.Miller, R.D., and J.G. Clough, 2002, Delineation of coal beds for coalbed methane using high-resolution seismic reflection at Ft. Yukon, Alaska (abstract): AAPG Annual Convention Official Program, v. 11, p. A122-123.

Milley, J., 1990, Redox potential curves as a rank parameter in coal geological and technological investigations: Journal of Coal Quality, v. 9, p. 1-8.Miranda, J.L., C. Romero, J.V. Ibarra, D. Schmal, and D. Martinez, 1994, Weathering of stockpiled coals and the resulting losses of calorific value: Journal of Coal Quality, v. 13, p. 104-112.Miranda, J.L., C. Romero, J.V. Ibarra, D. Schmal, and D. Martinez, 1994, Weathering of stockpiled coals and the resulting losses of calorific value: Journal of Coal Quality, v. 13, p. 104-112. (spontaneous combustion)Miranda, J.L., F. Aguilar, R. Juan, M.T. Martinez, and V.L. Cebolla, 1991, Effect of mineral matter on the hydrogenation of Spanish coals: Erdöl und Kohle-Erdgas-Petrochemie, v. 44, p. 333-337.Mirzaeian, M., and P.J. Hall, 2006, The interactions of coal with CO2 and its effects on coal structure: Energy & Fuels, v. 20, p. 2022-2027.

Merrow, J., 1957, Ozocerite at Soldier Summit, Utah, in O.G. Seal, ed., Guidebook to the geology of the Uinta basin: Intermountain Association of Petroleum Geologists, 8 th annual field conference, p. 161-164.

Metz, B., O. Davidson, H. deConinck, M. Loos, and L. Meyer, eds., 2005, Carbon dioxide capture and storage: Online, IPCC Special Report, http://www.ipcc.ch/pub/online.htm

Michelsen, J.K., and G. Khavari-Khorasani, 1999, The physics and efficiency of petroleum expulsion from coal, in M. Mastalerz, M. Glikson, and S.D. Golding, eds., Coalbed methane: scientific, environmental and economic evaluation: Boston, Kluwer Academic Publishers, p. 517-543.Michelsen, J.K., and G. Khavari-Khorasani, 1999, The physics and efficiency of petroleum expulsion from coal, in M. Mastalerz, M. Glikson, and S.D. Golding, eds., Coalbed methane: scientific, environmental and economic evaluation: Boston, Kluwer Academic Publishers, p. 517-543.

Milici, R.C., 2002, Coalbed methane production in the Appalachian Basin: U.S. Geological Survey, Open-File Report 02-105. (http://pubs.usgs.gov/of/2002/of02-105/)Milici, R.C., 2005, Appalachian coal assessment: defining the coal systems of the Appalachian Basin, in P.D. Warwick, ed., Coal systems analysis: Geological Society of America Special Paper 387, p. 9-30.

Mililci, R.C., 2004, The Pennsylvania anthracite district—a frontier area for the development of coalbed methane?, in P.D. Warwick, ed., Selected presentations on coal-bed gas in the eastern United States: U.S. Geological Survey Open File Report 2004-1273, p. 37-59. (http://pubs.usgs.gov/of/2004/1273/)

Miller, R.L., R.M. Baldwin, O. Nguanprasert, and D.R. Kennar, 1991, Effect of mild chemical pretreatment on liquefaction reactivity of Argonne coals, in H.H. Schobert, K.D. Bartle, and L.J. Lynch, eds., Coal science II: Washington, D.C., American Chemical Society, Symposium Series 461, p. 260-272.Miller, R.N., 1989, Effects of preparation, pretreatment, and oxidation on coal conversion, in R. Klein and R. Wellek, eds., Sample selection, aging, and reactivity of coal: New York, John Wiley & Sons, p. 357-404.

Miser, H.D., and A.H. Purdue, 1918, Asphalt deposits and oil conditions in southwestern Arkansas: U.S. Geological Survey Bulletin 691-J, p. 271-292.Mishra, H.K., and A.C. Cook, 1992, Petrology and thermal maturity of coals in the Jharia basin: implications for oil and gas origins: International Journal of Coal Geology, v. 20, p. 277-313.Mishra, S., Y.D. Oruganti, and J. Sminchak, 2014, Parametric analysis of CO2 geologic sequestration in closed volumes: Environmental Geosciences Journal, v. 21, no. 2.Misiak, J., 2006, Petrography and depositional environment of the No. 308 coal seam (Upper Silesian coal basin, Poland)—a new approach to maceral quantification and facies analysis: International Journal of Coal Geology, v. 68, p. 117-126.Misiak, J., 2006, Petrography and depositional environment of the No. 308 coal seam (Upper Silesian coal basin, Poland)—a new approach to maceral quantification and facies analysis: International Journal of Coal Geology, v. 68, p. 117-126.Misra, B.K., 1992, Spectral fluorescence analysis of some liptinite macerals from Panandhro lignite (Kutch), Gujarat, India: International Journal of Coal Geology, v. 20, p. 145-163.Misra, B.K., and B.D. Singh, 1993, Liptinite macerals in Singrauli coals, India: their characterization and assessment: The Palaeobotanist, v. 42, p. 1-13.Misra, B.K., and B.D. Singh, 1994, Susceptibility to spontaneous combustion of Indian coals and lignites: an organic petrographic autopsy: International Journal of Coal Geology, v. 25, p. 265-286.Misra, B.K., B.D. Singh, and A. Singh, 1998, Maceral alginite in Indian coals and lignites: its significance and influence: The Palaeobotanist, v. 47, p. 37-49.

Misra, B.K., B.D. Singh, and G.K.B. Navale, 1990, Resino-inertinites of Indian Permian coals—their origin, genesis and classification: International Journal of Coal Geology, v. 14, p. 277-293.Misra, B.K., R. Saxena, and A. Prakash, 1989, Spectrofluorimetric study of some resinites from Indian coals and lignites: The Palaeobotanist, v. 38, p. 188-195.Misz, M., M. Fabiańska, and S. Ćmiel, 2007, Organic compounds in thermally altered coal waste: Preliminary petrographic and geochemical investigations: International Journal of Coal Geology, v. 71, p. 405-424.Mitariten, M., 2002, Adsorption advances: World Coal, v. 11, p. 57-58, 60-61.Mitariten, M., 2002, Adsorption advances: World Coal, v. 11, p. 57-58, 60-61.

Mitchell, G.D., A. Davis, and R.F. Rathbone, 1991, The use of vitrinite fluorescence as a measure of changes in coal thermoplasticity and weathering: Proceedings Ironmaking Conference, v. 50, p. 199-206.Mitchell, G.D., A. Davis, and R.F. Rathbone, 1991, The use of vitrinite fluorescence as a measure of changes in coal thermoplasticity and weathering: Proceedings Ironmaking Conference, v. 50, p. 199-206.Mitchell, G.D., A. Davis, and S. Chander, 2005, Surface properties of photo-oxidized bituminous vitrains: International Journal of Coal Geology, v. 62, p. 33-47.Mitchell, G.D., A. Davis, and S. Chander, 2005, Surface properties of photo-oxidized bituminous vitrains: International Journal of Coal Geology, v. 62, p. 33-47.

Mito, S., Z. Xue, and T. Sato, 2013, Effect of formation water composition on predicting CO2 behavior: A case study at the Nagaoka post-injection monitoring site: Applied Geochemistry, v. 30, p. 33-40.Mitra, A., S. Harpalani, and S. Liu, 2012, Laboratory measurement and modeling of coal permeability with continued methane production: Part 1 – Laboratory results: Fuel, v. 94, p. 110-116.Miura, T., ed., 2001, Advanced coal combustion: Huntington, New York, Nova Science Publishers, 304 p.Miyazaki, S., 2005, Coalbed methane growing rapidly as Australia gas supply diversifies: Oil & Gas Journal, v. 103.28, p. 32-36.Miyazaki, S., and R.J. Korsch, 1993, Coalbed methane resources in the Permian of eastern Australia and their tectonic setting: APEA Journal, v. 33, part 1, p. 161-175.

Mochida, I., T. Shimohara, Y. Korai, and H. Fujitsu, 1984, Carbonization of coals to produce anisotropic cokes. 5. Structural factors of coals influencing carbonization properties: Fuel, v. 63, p. 847-853.Mochizuki, Y., Y. Ono, K. Uebo, and N. Tsubouchi, 2013, The fate of sulfur in coal during carbonization and its effect on coal fluidity: International Journal of Coal Geology, v. 120, p. 50-56.Moffat, D.H., and K.E. Weale, 1955, Sorption by coal of methane at high pressure: Fuel, v. 34, p. 449-462.Mohan, H., K. Biglarbigi, and M. Carolus, 2009, Study places CO2 capture cost between $34 and $61/ton: Oil & Gas Journal, v. 107.38, p. 56-65.Mohr, S.H., and G.M. Evans, 2007, Model proposed for world conventional, unconventional gas: Oil & Gas Journal, v. 105.47, p. 46-51.

Montgomery, S.L., 1986, Coalbed methane: an old hazard becomes a new resource: Petroleum Information, Petroleum Frontiers series, v. 3, 65 p.Montgomery, S.L., 1999, Powder River basin, Wyoming: an expanding coalbed methane (CBM) play: AAPG Bulletin, v. 83, p. 1207-1222.Montgomery, S.L., and C.E. Barker, 2003, Coalbed methane, Cook Inlet, south-central Alaska: a potential giant gas resource: AAPG Bulletin, v. 87, p. 1-13.Montgomery, S.L., and S. Morzenti, 2006, Underground coal gasification nears commercialization: Oil & Gas Journal, v. 104.13, p. 51-53, 56-58.Montgomery, S.L., D.E. Tabet, and C.E. Barker, 2001, Upper Cretaceous Ferron Sandstone: major coalbed methane play in central Utah: AAPG Bulletin, v. 85, p. 199-219.

Misra, B.K., B.D. Singh, and Anand-Prakash, 1996, Biopetrographic approach to the spontaneous combustion susceptibility of Indian Gondwana coals: with reference to some coals of Raniganj and Singrauli coalfields, in Gondwana nine, v. 2: Geological Survey of India, Ninth International Gondwana Symposium, p. 1257-1264.

Mitchell, E.R., 1974, Coal properties bearing on combustion, in J.F. Fryer, J.D. Campbell, and J.G. Speight, eds., Symposium on coal evaluation: Alberta Research Council, Information Series 76, p. 134-151.Mitchell, G.D., 2008, Direct coal liquefaction, in I. Suárez-Ruiz and J.C. Crelling, eds., Applied coal petrology: the role of petrology in coal utilization: New York, Academic Press, p. 145-171.

Mitchell, G.D., A. Davis, and W. Spackman, 1977, A petrographic classification of solid residues derived from the hydrogenation of bituminous coals, in R.T. Ellington, ed., Liquid fuels from coal: New York, Academic Press, p. 255-270.Mitchell, T.E., and S.P. Pappajohn, 1991, Coalbed methane production potential in complex geologic settings, in D.C. Peters, ed., Geology in coal resource utilization: Fairfax, VA, Techbooks, p. 137-151.

Mo, H.-J., W.-L. Huang, and H. Machnikowska, 2008, Generation and expulsion of petroleum from coal macerals visualized in-situ during DAC pyrolysis: International Journal of Coal Geology, v. 73, p. 167-184.

Monson, B., and J. Parnell, 1992, The origin of gilsonite vein deposits in the Uinta basin, Utah, in T.D. Fouch, V.F. Nuccio, and T.C. Chidsey, Jr., eds., Hydrocarbon and mineral resources of the Uinta basin, Utah and Colorado: Salt Lake City, Utah Geological Association Guidebook 20, p. 257-270. (also as Utah Geological Survey Contract Report CR-92-4, 27 p.)Montgomery, D.S., 1974, Coal properties bearing on coal liquefaction and gasification, in J.F. Fryer, J.D. Campbell, and J.G. Speight, eds., Symposium on coal evaluation: Alberta Research Council, Information Series 76, p. 152-160.

Moore, E.S., 1940, Coal, its properties, analysis, classification, geology, extraction, uses, and distribution (second edition): New York, John Wiley & Sons, 473 p.Moore, F., and A. Esmaeili, 2012, Mineralogy and geochemistry of the coals from the Karmozd and Kiasar coal mines, Mazandaran province, Iran: International Journal of Coal Geology, v. 96-97, p. 9-21.Moore, F., and A. Esmaeili, 2012, Mineralogy and geochemistry of the coals from the Karmozd and Kiasar coal mines, Mazandaran province, Iran: International Journal of Coal Geology, v. 96-97, p. 9-21.

Moore, P.D., 1989, Some ecological implications of palaeoatmospheric variations: Journal of the Geological Society, London, v. 146, p. 183-186.Moore, P.D., 1995, Biological processes controlling the development of modern peat-forming ecosystems: International Journal of Coal Geology, v. 28, p. 99-110.Moore, S.E., R.E. Ferrell, Jr., and P. Aharon, 1992, Diagenetic siderite and other ferroan carbonates in a modern subsiding marsh sequence: Journal of Sedimentary Petrology, v. 62, p. 357-366.Moore, T.A., 1991, The effects of clastic sedimentation on organic facies development within the Tertiary subbituminous coal bed, Powder River Basin, Montana, U.S.A.: International Journal of Coal Geology, v. 18, p. 187-209.Moore, T.A., 2012, Coalbed methane: a review: International Journal of Coal Geology, v. 101, p. 36-81.

Moore, T.A., and J.C. Shearer, 2003, Peat/coal type and depositional environment—are they related?: International Journal of Coal Geology, v.56, p. 233-252.Moore, T.A., and K.M. Swanson, 1993, Application of etching and SEM in the identification of fossil plant tissues in coal: Organic Geochemistry, v. 20, p. 769-777.Moore, T.A., and R.W. Stanton, 1985, Coal petrographic laboratory procedures and safety manual: U.S. Geological Survey Open-File Report 85-20, 68 p. (see Pontolillo and Stanton, 1994, for revision)Moore, T.A., J.C. Shearer, and J.S. Esterle, 1993, Quantitative macroscopic textural analysis: TSOP Newsletter, v. 9, no. 4, p. 13-16.Moore, T.A., J.C. Shearer, and S.L. Miller, 1996, Fungal origin of oxidized plant material in the Palangkaraya peat deposit, Kalimantan Tengah, Indonesia: implications for ‘inertinite’ formation in coal: International Journal of Coal Geology, v. 30, p. 1-23.Moore, T.A., R.M. Flores, R.W. Stanton, and G.D. Stricker, 2002, The role of macroscopic texture in determining coal bed methane variability in the Anderson-Wyodak coal seam, Powder River basin, Wyoming (abstract): TSOP Abstracts and Program, v. 18, p. 85-88.Moore, T.A., R.W. Stanton, D.T. Pocknall, and R.M. Glores, 1990, Maceral and palynomorph facies from two Teriary peat-forming environments in the Powder River Basin, U.S.A.: International Journal of Coal Geology, v. 15, p. 293-316.

Moreland, A., J.W. Patrick, and A. Walker, 1988, Optical anisotropy in cokes from high-rank coals: Fuel, v. 67, p. 730-732.Morga, R., 2010, Chemical structure of semifusinite and fusinite of steam and coking coal from the Upper Silesian Coal Basin (Poland) and its changes during heating as inferred from micro-FTIR analysis: International Journal of Coal Geology, v. 84, p. 1-15.Morga, R., 2011, Changes of semifusinite and fusinite surface roughness during heat treatment determined by atomic force microscopy: International Journal of Coal Geology, v. 88, p. 218-226.Morga, R., 2011, Micro-Raman spectroscopy of carbonized semifusinite and fusinite: International Journal of Coal Geology, v. 87, p. 253-267.Morga, R., 2011, Reactivity of semifusinite and fusinite in the view of micro-Raman spectroscopy examination: International Journal of Coal Geology, v. 88, p. 194-203.Moritis, G., 2003, CO2 sequestration adds new dimension to oil, gas production: Oil & Gas Journal, v. 101.9, p. 39-44.Moritis, G., 2005, Norway study finds CO2 EOR too expensive, risky: Oil & Gas Journal, v. 103.30, p. 37-38.Moritis, G., 2005, Numerous studies analyze CO2 sequestration options: Oil & Gas Journal, v. 103.33, p. 42-47.Moritis, G., 2008, Oil shale promise: Oil & Gas Journal, v. 106.41, p. 16.Moritis, G., 2008, SWP advances CO2 sequestration, ECBM, EOR demos: Oil & Gas Journal, v. 106.37, p. 60-63.Moritis, G., 2009, Oil shale adds to energy mix: Oil & Gas Journal, v. 107.42, p. 14.Mørk, M.B.E., 2013, Diagenesis and quartz cement distribution of low-permeability Upper Triassic-Middle Jurassic reservoir sandstones, Longyearbyen CO2 lab well site in Svalbard, Norway: AAPG Bulletin, v. 97, p. 577-596.Morris, G.DL, 2011, CBM development regs give industry balance: American Oil & Gas Reporter, v. 54, no. 11, p. 158-159.Morrison, G.F., 1986, Understanding pulverised coal combustion: IEA Coal Research, London, 26 p.Morrow, D.W., and D.R. Issler, 1993, Calculation of vitrinite reflectance from thermal histories: a comparison of some methods: AAPG Bulletin, v. 77, p. 610-624.Morse, D.G., M. Mastalerz, A. Drobniak, J.A. Rupp, and S. Harpalani, 2010, Variations in coal characteristics and their possible implications for CO2 sequestration: Tanquary injection site, southeastern Illinois, USA: International Journal of Coal Geology, v. 84, p. 25-38.Morton, M.C., 2010, Centralia, Pa.: Hot as hell: Earth, v. 55, no. 5, p. 28-32.Moschovidis, Z.A., J.R. Cameron, and I.D. Palmer, 2005, Methodology and examples of wellbore stability in coalbed methane wells: 2005 International Coalbed Methane Symposium, Tuscaloosa, AL, Paper 0517, 13 p.

Mosher, K., J. He, Y. Liu, E. Rupp, and J. Wilcox, 2013, Molecular simulation of methane adsorption in micro- and mesoporous carbons with applications to coal and gas shale systems: International Journal of Coal Geology, v. 109-110, p. 36-44.

Moore, L.R., 1968, Cannel coals, boghead and oil shales, in D.G. Murchison and T.S. Westoll, eds., Coal and coal-bearing strata: Edinburgh, Oliver & Boyd, p. 19-28.Moore, L.R., 1968, Cannel coals, bogheads and oil shales, in D. Murchison and S.T. Westoll, eds., Coal and coal-bearing strata: Oliver and Boyd, Edinburgh, p. 19-28.Moore, P.D., 1987, Ecological and hydrological aspects of peat formation, in A.C. Scott, ed., Coal and coal-bearing strata: recent advances: Boston, Blackwell Scientific Publications, Geological Society Special Publication 32, p. 7-15.Moore, P.D., 1987, Ecological and hydrological aspects of peat formation, in A.C. Scott, ed., Coal and coal-bearing strata: recent advances: Geological Society Special Publication 32, p. 7-15.

Moore, T.A., and J.C. Shearer, 1993, Processes and possible analogues in the formation of Wyoming’s coal deposits, in A.W. Snoke, J.R. Steidtmann, and S.M. Roberts, eds., Geology of Wyoming: Wyoming State Geological Survey, Memoir 5, p. 874-896.

Moore, T.A., Z. Li, and N.A. Moore, 2006, Controls on the formation of an anomalously thick Cretaceous-age coal mire, in S.F. Greb and W.A. DiMichele, eds., Wetlands through time: Geological Society of America Special Paper 399, p. 269-290.

Mosgrove, J.H., 1973, Mine gases, in S.M. Cassidy, ed., Elements of practical coal mining: New York, Society of Mining Engineers of the American Institute of Mining, Metallurgical, and Petroleum Engineers, p. 187-205.

Moss, T.D., K.W. Riley, J.D. Saxby, C.J.R. Fookes, and J.H. Patterson, 1988, Effect of weathering of oil shale at Julia Creek (Australia) on kerogen, oil yields and oil properties: Fuel, v. 67, p. 1382-1385.Mossman, D.J., and B. Nagy, 1996, Solid bitumens: an assessment of their characteristics, genesis, and role in geological processes: Terra Nova, v. 8, p. 114-128.Mossman, D.J., and C.L. Thompson-Rizer, 1993, Toward a working nomenclature and classification of organic matter in Precambrian (and Phanerozoic) sedimentary rocks: Precambrian Research, v. 61, p. 171-179.Moura, J.C. de, A. de Moraes Rios-Netto, M.D. Wanderley, and F.P. de Sousa, 1999, Using acids to extract calcareous microfossils from carbonate rocks: Micropaleontology, v. 45, p. 429-436.Moxon, N.T., J. McLellan, and P.R. Warbrooke, 1986, The effect of ash on the laboratory carbonization properties of coal: Journal of Coal Quality, v. 5, no. 2, p. 76-78.Moxon, N.T., J. McLellan, and P.R. Warbrooke, 1986, The effect of ash on the laboratory carbonization properties of coal: Journal of Coal Quality, v. 5, p. 76-78.

Mroz, T.H., J.G. Ryan, and C.W. Byrer, eds., 1983, Methane recovery from coalbeds - a potential energy source: USDOE Morgantown Energy Technology Center Report DOE/METC/83-76, 458 p.Mudamburi, Z., and P.H. Given, 1985, Multifaceted study of a Cretaceous coal with algal affinities—II. Composition of liquefaction products: Organic Geochemistry, v. 8, p. 221-231.Mudamburi, Z., and P.H. Given, 1985, Some chemical structural features of coals of differing maceral distributions and stratigraphy: Organic Geochemistry, v. 8, p. 441-453.Mueller, E., R.P. Philp, and J. Allen, 1995, Geochemical characterization and relationship of oils and solid bitumens from SE Turkey: Journal of Petroleum Geology, v. 18, p. 289-307.Muhammad, A.B., and G.D. Abbott, 2013, The thermal evolution of asphaltene-bound biomarkers from coals of different rank: A potential information resource during coal biodegradation: International Journal of Coal Geology, v. 107, p. 90-95.Muir, M.D., and W.A. Sargeant, 1977, Palynology, part I: spores and pollen: Van Nostrand Reinhold Benchmark Papers in Geology, v. 46, 400 p.Muir, M.D., and W.A. Sargeant, 1977, Palynology, part II: dinoflagellates, acritarchs, and other microfossils: Van Nostrand Reinhold Benchmark Papers in Geology, v. 47, 432 p.Muir, W.L.G., ed., 1976, Coal exploration, v. 1: San Francisco, Miller Freeman Publications, Inc., 664 p.Mukherjee, D.P., D.K. Banerjee, B.U. Shankar, and D.D. Majumder, 1994, Coal petrography: a pattern recognition approach: International Journal of Coal Geology, v. 25, p. 155-169.Mukhopadhyay, P. K, Calder, J. H. and Hatcher, P. G., 1993, Geological andphysicochemical constraints on methane and C6+ hydrocarbon generating capabilities and quality of Carboniferous coals, Cumberland Basin, Nova Scotia, Canada: Proc. 10th Annual International Pittsburgh Coal Conference, p. 1074-1079.

Mukhopadhyay, P. K., MacDonald, D. J. and Calder, J. H.,1995, Evaluation ofcoalbed methane potential of the Stellarton Basin, Nova Scotia, Canada, basedon geological, physical, and geochemical properties: Proceedings InternationalGas Conference (INTERGAS '95), Tuscaloosa, Alabama, Paper 9505, p. 311-320.

Mukhopadhyay, P.K., 1989, Characterization of amorphous and other organic matter types by microscopy and pyrolysis-gas chromatography: Organic Geochemistry, v. 14, p. 269-284.Mukhopadhyay, P.K., 1989, Organic petrography and organic geochemistry of Texas Tertiary coals in relation to depositional environment and hydrocarbon generation: Austin, University of Texas, Bureau of Economic Geology, Report of Investigations 188,

Mukhopadhyay, P.K., and J.R. Gormly, 1984, Hydrocarbon potential of two types of resinite: Organic Geochemistry, v. 6, p. 439-454.

Mukhopadhyay, P.K., and W.G. Dow, eds., 1994, Vitrinite reflectance as a maturity parameter: applications and limitations: American Chemical Society Symposium Series 570, 294 p.Mukhopadhyay, P.K., and W.G. Dow, eds., 1994, Vitrinite reflectance as a maturity parameter: applications and limitations: Washington, D.C., American Chemical Society Symposium Series 570, 294 p.Mukhopadhyay, P.K., F. Goodarzi, M.A. Kruge, and M.H. Alimi, 1997, Comparison of source rock geochemistry of selected rocks from the Schei Point group and Ringnes formation, Sverdrup basin, arctic Canada: International Journal of Coal Geology, v. 34, p. 225-260.Mukhopadhyay, P.K., G. Lajeunesse, A.L. Crandlemire, and R.B. Finkelman, 1999, Mineralogy and geochemistry of selected coal seams and their combustion residues from the Sydney area, Nova Scotia, Canada: International Journal of Coal Geology, v. 40, p. 253-254.Mukhopadhyay, P.K., G. Lajeunesse, and A.L. Crandlemire, 1996, Mineralogical speciation of elements in an eastern Canadian feed coal and their combustion residues from a Canadian power plant: International Journal of Coal Geology, v. 32, p. 279-312.Mukhopadhyay, P.K., H.W. Hagemann, A. Hollerbach, and D.H. Welte, 1979, The relation between organic geochemical and petrological parameters of coal in Indian coal basins: Energy Sources, v. 4, p. 313-328.Mukhopadhyay, P.K., H.W. Hagemann, and J.R. Gormly, 1985, Characterization of kerogens as seen under the aspect of maturation and hydrocarbon generation: Erdol und Kohle - Erdgas - Petrochemie, v. 38, p. 7-18.Mukhopadhyay, P.K., J.R. Gormly, and J.E. Zumberge, 1989, Generation of hydrocarbons from the Tertiary coals of Texas - coal as potential source rock for liquid hydrocarbons in a deltaic basin?: Organic Geochemistry, v. 14, p. 351-352.

Mraw, S.C., J.P. De Neufville, H. Freund, Z. Baset, M.L. Gorbaty, and F.J. Wright, 1983, The science of mineral matter in coal, in M.L. Gorbaty, J.W. Larsen, and I. Wender, eds., Coal science, v. 2: New York, Academic Press, p. 1-63.Mraw, S.C., J.P. De Neufville, H. Freund, Z. Baset, M.L. Gorbaty, and F.J. Wright, 1983, The science of mineral matter in coal, in M.L. Gorbaty, J.W. Larsen, and I. Wender, eds., Coal science, v. 2: New York, Academic Press, p. 1-63. (combustion p. 26-42)Mraw, S.C., J.P. de Neufville, H. Freund, Z. Baset, M.L. Gorbaty, and F.J. Wright, 1983, The science of mineral matter in coal, in M.L. Gorbaty, J.W. Larsen, and I. Wender, eds., Coal science, v. 2: New York, Academic Press, p. 1-63. (gasification and liquefaction, p. 42-48)Mroz, T.H., 2009, The history of US DOE unconventional energy resources in the US, an archive of references available for application of current oil shale and tar sand resources, in T. Carr, T. D’Agostino, W. Ambrose, J. Pashin, and N.C. Rosen, eds., Unconventional energy resources: making the unconventional conventional: 29 th Annual GCSSEPM Foundation Bob F. Perkins Research Conference, CD-ROM, p. 396.

Mukhopadhyay, P. K. and Hatcher, P. G., 1993, Composition of coal, inB.E. Law and D.D. Rice, eds., Hydrocarbons from coal: American Association of Petroleum Geologists Studies in Geology, v. 38, p. 79-118.

Mukhopadhyay, P.K. and J.R. Gormly, 1984, Hydrocarbon potential of two types of resinite, in P.A. Schenck, J.W. de Leeuw, and G.W.M. Lumbach, eds., Advances in Organic Geochemistry 1983: New York, Pergamon Press, p. 439-454.

Mukhopadhyay, P.K., 1992, Maturation of organic matter as revealed by microscopic methods: applications and limitations of vitrinite reflectance, and continuous spectral and pulsed laser fluorescence spectroscopy, in K.H. Wolf and G.V. Chilingarian, eds., Diagenesis, III: New York, Elsevier, Developments in Sedimentology 47, p. 435-510.Mukhopadhyay, P.K., 1992, Maturation of organic matter as revealed by microscopical methods: applications and limitations of vitrinite reflectance, and continuous spectral and pulsed laser fluorescence spectroscopy, in K.H. Wolf and G.V. Chilingarian, eds., Diagenesis III: Elsevier, Developments in Sedimentology 47, p. 435-510.Mukhopadhyay, P.K., 1992, Maturation of organic matter as revealed by microscopical methods: applications and limitations of vitrinite reflectance, and continuous spectral and pulsed laser fluorescence spectroscopy, in K.H. Wolf and G.V. Chilingarian, eds., Diagenesis III: Elsevier, Developments in Sedimentology 47, p. 435-510.Mukhopadhyay, P.K., 1994, Vitrinite reflectance as maturity parameter: petrographic and molecular characterization and its applications to basin modeling, in P.K. Mukhopadhyay and W.G. Dow, eds., Vitrinite reflectance as a maturity parameter: applications and limitations: Washington, D.C., American Chemical Society Symposium Series 570, p. 1-24.Mukhopadhyay, P.K., 1994, Vitrinite reflectance as maturity parameter: petrographic and molecular characterization and its applications to basin modeling, in P.K. Mukhopadhyay and W.G. Dow, eds., Vitrinite reflectance as a maturity parameter: applications and limitations: Washington, D.C., American Chemical Society Symposium Series 570, p. 1-24.Mukhopadhyay, P.K., 1994, Vitrinite reflectance as maturity parameter: petrographic and molecular characterization and its applications to basin modeling, in P.K. Mukhopadhyay and W.G. Dow, eds., Vitrinite reflectance as a maturity parameter: applications and limitations: American Chemical Society Symposium Series 570, p. 1-24.

Mukhopadhyay, P.K., and P.G. Hatcher, 1993, Composition of coal, in B.E. Law and D.D. Rice, eds., Hydrocarbons from coal: American Association of Petroleum Geologists Studies in Geology 38, p. 79-118.

Mukhopadhyay, P.K., M.G. Fowler, and W.G. Dow, eds., 1991, Selected papers from the symposium on coal and terrestrial organic matter as a source rock for petroleum: Organic Geochemistry, v. 17, p. 671-875.Mukhopadhyay, P.K., M.G. Fowler, and W.G. Dow, eds., 1991, Selected papers from the symposium on coal and terrestrial organic matter as a source rock for petroleum: Organic Geochemistry, v. 17, p. 671-875.Mukhopadhyay, P.K., MacDonald, D.J, Calder, J. H., Hughes, J. D., and Hatcher, P.G., 1997, Relationship between methane generation/adsorption potential, micropore system, and permeability with composition and maturation – Examples from Carboniferous coals of Nova Scotia, eastern Canada: Proc. International Coalbed Methane Symposium, Tuscaloosa, Alabama, Paper 9733, p. 183-193.

Mukhrejee, D.P., D.K. Banerjee, B.U. Shankar, and D.D. Majumder, 1994, Coal petrography: a pattern recognition approach: International Journal of Coal Geology, v. 25, p. 155-169.

Muller, H., 1987, Jet: Boston, Butterworths Gem Books, 149 p.Murchison, D., 2006, The influence of heating rates on organic matter in laboratory and natural environments: International Journal of Coal Geology, v. 67, p. 145-157.Murchison, D.C., 1991, Petrographic aspects of coal structure: reactivity of macerals in laboratory and natural environments: Fuel, v. 70, p. 296.Murchison, D.G., 1958, Reflectance of vitrinite: Brennst.-Chemie, v. 39, p. 47-51.

Murchison, D.G., 1976, Resinite: its infrared spectrum and coalification pattern: Fuel, v. 55, p. 79-83.

Murchison, D.G., 1991, Petrographic aspects of coal structure: reactivity of macerals in laboratory and natural environments: Fuel, v. 70, p. 296-315.Murchison, D.G., 2004, Aberrations in the coalfication patterns of the offshore coalfields of Northumberland and Durham, United Kingdom: International Journal of Coal Geology, v. 58, p. 133-146.Murchison, D.G., 2004, Aberrations in the coalfication patterns of the offshore coalfields of Northumberland and Durham, United Kingdom: International Journal of Coal Geology, v. 58, p. 133-146.Murchison, D.G., 2006, The influence of heating rates on organic matter in laboratory and natural environments: International Journal of Coal Geology, v. 67, p. 145-157.

Murchison, D.G., and J.M. Jones, 1963, Properties of the coal macerals: elementary composition of resinite: Fuel, v. 42, p. 141-158.

Murchison, D.G., J. Pearson, and A.C. Raymond, 1991, Anomalies in vitrinite reflectance gradients: Bulletin de la Societe Geologique de France, v. 162, p. 183-191.Murphy, E., 2009, Germanium in North Dakota lignites: North Dakota Department of DMR Mineral Resources Newsletter, v. 36, no. 1, p. 12-13.

Murray, D. K., 2003, Natural gas from deep coal beds: a promising resource of worldwide importance: Tuscaloosa, Alabama, University of Alabama, College of Continuing Studies, 2003 International Coalbed Methane Symposium Proceedings, paper 0335, 14 p.

Murray, D.K., 2000, CBM in the United States: World Coal, March, p. 61-64.

Murray, D.K., 2002, Deep coals hold big part of resource: American Oil & Gas Reporter, v. 45, no. 5, p. 73-74, 76-81.

Murray, J., 2012, Australia extends gas development to CBM: Hart Energy Publishing, E&P, v. 85, no. 2, p. 37-38.Murrie, G.W., 1977, Coal and gas resources of the Lower Hartshorne coalbed in Le Flore and Haskell Counties, Oklahoma (abstract): GSA Abstracts with Programs, v. 9, no. 1, p. 65-66.Murrie, G.W., W.P. Diamond, and S.W. Lambert, 1976, Geology of the Mary Lee group of coalbeds, Black Warrior coal basin, Alabama: U.S. Bureau of Mines Report of Investigations 8189, 49 p.Mutmansky, J.M., 1999, Guidebook on coalbed methane drainage for underground coal mines: U.S. Environmental Protection Agency, Coalbed Methane Outreach Program, Document No. 60938, 46 p.

Mukhopadhyay, P.K., P.G. Hatcher, and J.H. Calder, 1991, Hydrocarbon generation from deltaic and intermontane fluviodeltaic coal and coaly shale from the Tertiary of Texas and Carboniferous of Nova Scotia, in P.K. Mukhopadhyay, M.G. Fowler, and W.G. Dow, eds., Selected papers from the symposium on coal and terrestrial organic matter as a source rock for petroleum: Organic Geochemistry, v. 17, p. 765-783.

Mullen, M.J., 1988, Log evaluation in wells drilled for coal-bed methane, in J.E. Fassett, ed., Geology and coal-bed methane resources of the northern San Juan basin, Colorado and New Mexico: Denver, Rocky Mountain Association of Geologists Guidebook, p. 113-124.Mullen, M.J., 1988, Log evaluation in wells drilled for coalbed methane, in J.E. Fassett, ed., Geology and coal-bed methane resources of the northern San Juan basin, Colorado and New Mexico: Denver, Rocky Mountain Association of Geologists, p. 113-124.Mullen, M.J., 1991, Cleat detection in coalbeds using the microlog, in S.D. Schwochow, D.K. Murray, and M.F. Fahy, eds., Coalbed methane of western North America: Denver, Rocky Mountain Association of Geologists, p. 137-147.

Murchison, D.G., 1966, Properties of coal macerals: infrared spectra of resinites and their carbonized and oxidized products, in R.F. Gould, ed., Coal Science: American Chemical Society Advances in Chemistry Series 55, p. 307-331.

Murchison, D.G., 1978, Optical properties of carbonized vitrinites, in C. Karr, Jr., ed., Analytical methods for coal and coal products, v. 2: New York, Academic Press, p. 415-464.Murchison, D.G., 1978, Optical properties of carbonized vitrinites, in C. Karr, Jr., ed., Analytical methods for coal and coal products, v. 2: New York, Academic Press, p. 415-464.Murchison, D.G., 1987, Recent advances in organic petrology and organic geochemistry: an overview with some reference to ‘oil from coal’, in A.C. Scott, ed., Coal and coal-bearing strata: Boston, Blackwell Scientific Publications, Geological Society Special Publication 32, p. 257-302.Murchison, D.G., 1987, Recent advances in organic petrology and organic geochemistry: an overview with some reference to 'oil from coal', in A.C. Scott, ed., Coal and coal-bearing strata: recent advances: Boston, Blackwell Scientific Publications, Geological Society Special Publication 32, p. 257-302.

Murchison, D.G., A.C. Cook, and A.C. Raymond, 1985, Optical properties of organic matter in relation to thermal gradients and structural deformation, in Geochemistry of buried sediments: Phil. Trans. R. Soc. London, Ser. A, v. 315, no. 1531, p. 157-186.

Murchison, D.G., J. Pearson, and A.C. Raymond, 1991, Anomalies in vitrinite reflectance gradients, in P. Bertrand, ed., Coal: formation, occurrence and related properties: Bull. Soc. Geol. France, v. 162, p. 183-191.Murchison, D.G., J. Pearson, and A.C. Raymond, 1991, Anomalies in vitrinite reflectance gradients, in P. Bertrand, ed., Coal: formation, occurrence and related properties: Bulletin de la Societe Geologique de France, v. 162, p. 183-191.

Murray, A.N., 1950, The gilsonite deposits of the Uinta basin, Utah, in Petroleum geology of the Uintah basin: Intermountain Association of Petroleum Geologists Guidebook to the geology of Utah, no. 5, Utah Geological and Mineralogical Survey, p. 115-120.

Murray, D.K., 1991, Coalbed methane: natural gas resources from coal seams, in D.C. Peters, ed., Geology in coal resource utilization: Fairfax, VA, Techbooks, p. 97-103.Murray, D.K., 1996, Coalbed methane in the USA: analogues for worldwide development, in R. Gayer and I.. Harris, eds., Coalbed methane and coal geology: London, Geological Society Special Publication 109, p. 1-12.

Murray, D.K., 2001, Anthracite: a potentially significant producer of coalbed methane, in M.R. Silverman, ed., Emerging coalbed methane plays of North America: Denver, CO, Petroleum Frontiers, v. 18, no. 3, p. 51-60.

Murray, D.K., 2003, Anthracite: a potentially significant producer of coalbed methane, in Emerging coalbed methane plays of North America, part 1: Petroleum Frontiers, v. 18, no. 3, p. 51-60.

Mutmansky, J.M., 1999, Guidebook on coalbed methane drainage for underground coal mines: U.S. Environmental Protection Agency, EPA Document 60938, 46 p. (available at EPA Coalbed Methane Outreach Program web site: www.epa.gov/coalbed, see CMOP Library, CMOP Reports)

Myers, M., L. Stalker, B. Pejcic, and A. Ross, 2013, Tracers—Past, present and future applications in CO2 geosequestration: Applied Geochemistry, v. 30, p. 125-135.

Nadon, G.C., 1998, Magnitude and timing of peat-to-coal compaction: Geology, v. 26, p. 727-730.

Nádudvari, Á., 2014, Thermal mapping of self-heating zones on coal waste dumps in Upper Silesia (Poland)—A case study: International Journal of Coal Geology, v. 128-129, p. 47-54.Nakamura, N., Y. Togino, and M. Tateoka, 1978, Behavior of coke in a large blast furnace: Ironmaking and Steelmaking, v. 5, p. 1-7.Nandi, B.N., and D.S. Montgomery, 1967, Thermal behaviour of massive and granular micrinite: Fuel, v. 46, p. 394-398.Nandi, B.N., and D.S. Montgomery, 1975, Nature and thermal behaviour of semi-fusinite in Cretaceous coal from western Canada: Fuel, v. 54, p. 193-196.Nandi, B.N., L.A. Ciavaglia, and D.S. Montgomery, 1977, The variation of the microhardness and reflectance of coal under conditions of oxidation simulating weathering: Journal of Microscopy, v. 109, p. 93-103.Nandi, B.N., T.D. Brown, and G.K. Lee, 1977, Inert coal macerals in combustion: Fuel, v. 56, p. 125-130.Narasimhan, K.S., A.K. Mukherjee, S. Sengupta, S.M. Singh, and M.M. Alam, 1998, Coalbed methane potential in India: Fuel, v. 22, p. 1865-1866.

National Petroleum Council, 1980, Unconventional gas sources, v.2, coal seams: National Petroleum Council, 46 p.Natras, T., I. McIlreath, S. Segal, and D. Bourgeois, 2007, Drill better CBM wells: Hart’s E&P, v. 80, no. 6, p. 103-105.Navale, G.K.B., 1963, Coal; a palyno-petrographic approach: Journal of the Geological Society of India, v. 4, p. 68-78.Nayak, R.V., F.W. Bauer, and T.P. Tonden, 1987, Mineral matter in coal -- origin, identification, high-temperature transformation, and boiler erosion: Journal of Coal Quality, v. 6, p. 37-43.Nayak, R.V., F.W. Bauer, and T.P. Tonden, 1987, Mineral matter in coal — origin, identification, high-temperature transformation, and boiler erosion: Journal of Coal Quality, v. 6, p. 37-43.Neavel, R.C., 1966, Sulfur in coal: its distribution in the seam and in mine products: Pennsylvania State University, unpublished PhD dissertation.

Neavel, R.C., 1976, Liquefaction of coal in hydrogen-donor and non-donor vehicles: Fuel, v. 55, p. 237-242.

Neavel, R.C., 1986, Coal science: an idiosyncratic view: Fuel, v. 65, p. 1632-1637.Neavel, R.C., and G.K. Guennel, 1960, Indiana paper coal: composition and deposition: Journal of Sedimentary Petrology, v. 30, p. 241-248.Neavel, R.C., and L.V. Miller, 1960, Properties of cutinite: Fuel, v. 39, p. 217-222.Neill, P.H., L.J. Shadle, and P.H. Given, 1988, Dependence of coal liquefaction behaviour on coal characteristics. 9. Liquefaction of a large set of high-sulphur coal samples: Fuel, v. 67, p. 1459-1464.Nelson, C. R., 2003, Reservoir property analysis methods for low gas content, subbituminous coals: Tuscaloosa, Alabama, University of Alabama, College of Continuing Studies, 2003 International Coalbed Methane Symposium Proceedings, paper 0326, 14 p.Nelson, C. R., 2004, Effect of vertical degasification wells on coal seam gas content reduction at the Oak Grove Field, Black Warrior basin, Alabama: Tuscaloosa, Alabama, University of Alabama, College of Continuing Studies, 2004 International Coalbed Methane Symposium Proceedings, paper 0428, 14 p.

Nelson, C.R., 1997, Advances in coalbed reservoir gas-in-place analysis: GRI Gas Tips, v. 4, no. 1, p. 14-19.Nelson, C.R., 1999, Changing perceptions regarding the size and production potential of coalbed methane resources: GTI Gas Tips, v. 5, no. 2, p. 4-11.Nelson, C.R., 1999, Common sources of error in coalbed gas resource and reservoir gas-in-place values (abstract): AAPG Bulletin, v. 83, p. 1372.Nelson, C.R., 1999, Gem in the rough; technology, economics putting new shine on coalbed methane: American Oil & Gas Reporter, v.42, no. 3, p. 84-92.Nelson, C.R., 2000, Coalbed methane potential of the U.S. Rocky Mountain region: GTI Gas Tips, v. 6, no. 3, p. 4-12.Nelson, C.R., 2000, New methods for coalbed reservoir gas-in-place analysis: results from case studies in the San Juan, Powder River, Black Warrior, and central Appalachian basins: Gas Research Institute, 12 p.Nelson, C.R., 2001, Geologic controls on effective cleat porosity variation in San Juan basin Fruitland Formation coalbed reservoirs: Tuscaloosa, Alabama, Proceedings, International Coalbed Methane Symposium, Paper 108, p. 11-19.

Nadkarni, R.A., 1982, Comprehensive elemental analysis of coal and fly ash, in E.L. Fuller, Jr., ed., Coal and coal products: analytical characterization techniques: American Chemical Society ACS Symposium Series 205, p. 147-162.Nadkarni, R.A., 1982, Comprehensive elemental analysis of coal and fly ash, in E.L. Fuller, Jr., ed., Coal and coal products: analytical characterization techniques: American Chemical Society, ACS Symposium Series 205, p. 147-162.

Nadon, G.C., and R.R. Kelly, 2004, The constraints of glacial eustasy and low accommodation on sequence-stratigraphic interpretations of Pennsylvanian strata, Conemaugh Group, Appalachian Basin, U.S.A., in J.C. Pashin and R.A. Gastaldo, eds., Sequence stratigraphy, paleoclimate, and tectonics of coal-bearing strata: AAPG Studies in Geology 51, p. 29-44.

NATCARB (National Carbon Sequestration Database and Geographic Information System), 2005, A project of the Kansas Geological Survey funded by Department of Energy National Energy Technology Laboratory. http://www.natcarb.org

Neavel, R.C., 1976, Coal plasticity mechanism: inferences from liquefaction studies, in C.J. Smith, compiler, Proceedings of the coal agglomeration and conversion symposium: West Virginia Geological and Economic Survey, p. 119-133.

Neavel, R.C., 1981, Origin, petrography and classification of coal, in M.A. Elliott, ed., Chemistry of coal utilization, 2nd supplementary volume: New York, Wiley, p. 91-158.Neavel, R.C., 1981, Origin, petrography and classification of coal, in M.A. Elliott, ed., Chemistry of coal utilization, second supplementary volume: New York, John Wiley and Sons, p. 91-158.Neavel, R.C., 1981, Origin, petrography, and classification of coal, in M.A. Elliott, ed., Chemistry of coal utilization, second supplementary volume: New York, John Wiley & Sons, p. 91-158.Neavel, R.C., 1981, Origin, petrography, and classification of coal, in M.A. Elliott, ed., Chemistry of coal utilization, second supplementary volume: New York, John Wiley & Sons, p. 91-158.Neavel, R.C., 1982, Coal plasticity mechanism: inferences from liquefaction studies, in M.L. Gorbaty, and others, eds., Coal science, v. 1: New York, Academic Press, p. 1-19.Neavel, R.C., 1982, Coal plasticity mechanism: inferences from liquefaction studies, in M.L. Gorbaty, and others, eds., Coal science, v. 1: New York, Academic Press, p. 1-19.

Nelson, C.R., 1989, Coal weathering: chemical processes and pathways, in C.R. Nelson, ed., Chemistry of coal weathering: New York, Elsevier Science Publishers, Coal Science and Technology, v. 14, p. 1-32.

Nelson, C.R., and T.J. Pratt, 2001, In coalbed gas plays, reservoir variables key to success: American Oil & Gas Reporter, v. 44, no. 3, p. 78-87.Nelson, C.R., ed., 1989, Chemistry of coal weathering: New York, Elsevier Science Publishers, Coal Science and Technology, v. 14, 230 p.Nelson, C.R., M.J. Mavor, T.J. Pratt, and T.A. Casey, 1997, Protocol ups coal seam gas analysis: American Oil & Gas Reporter, v. 40, p. 86-89.

Nelson, P.F., P. Shah, V. Strezov, B. Halliburton, and J.N. Carras, 2010, Environmental impacts of coal combustion: A risk approach to assessment of emissions: Fuel, v. 89, p. 810-816.Nelson, W.J., D.L. Eggert, W.A. Dimichele, and A.C. Stecyk, 1985, Origin of discontinuities in coal-bearing strata at Roaring Creek (basal Pennsylvanian of Indiana): International Journal of Coal Geology, v. 4, p. 355-370.Neufelder, R.J., B.B. Bowen, R.W. Lahann, and J.A. Rupp, 2012, Lithologic, mineralogical, and petrophysical characteristics of the Eau Claire Formation: Complexities of a carbon storage system: Environmental Geosciences Journal, v. 19, no. 3.

Newell, D.D., J.P. Lange, and T.A. Johnson, 2004, Analysis of Marmaton and Cherokee Group core samples for gas content--Layne Christensen #3-9 Scott well, (S2 NE NW Sec. 9-T.33S.-R.16E.) Montgomery County, Kansas: Kansas Geological Survey Open-File Report 2004-53, 58p.Newell, K.D, 2002, Analysis of Cherokee Group cuttings samples for gas content--Colt Energy #1 Honeycutt well (sec. 6-T.31S.-R.17E), Montgomery County, Kansas: Kansas Geological Survey, Kansas Geological Survey, Open-file Report 2002-72, 16p.Newell, K.D., 2003, Analysis of Cherokee Group cuttings samples for gas content--Devon Energy #35-1 R. John well (sec. 35-T.29S.-R.18E), Neosho County, Kansas: Kansas Geological Survey,Open-file Report 2003-83, 23p.Newell, K.D., 2004, Analysis of Cherokee Group cuttings samples for gas content--Meritage KCM #6-32 Broyles (SW SE 6.T.23S.-R.22E), Linn County, Kansas: Kansas Geological Survey, Open-file Report 2004-52, 35p.Newell, K.D., 2004, Analysis of Marmaton and Cherokee Group core samples for gas content--Dart Cherokee Basin Operating Company, Butler #A3-35; sec. 35-T.33S.-R.14E; Montgomery County, Kansas: Kansas Geological Survey, Open-file Report 2004-54, 23p.Newell, K.D., 2007, Wellsite, laboratory, and mathematical techniques for determining sorbed gas content of coals and gas shales utilizing well cuttings: Natural Resources Research, v. 16, p. 55-66.Newell, K.D., 2010, Fall may be imminent for Kansas Cherokee basin coalbed methane gas output: Oil & Gas Journal, v. 108.5, p. 33-40.

Newell, K.D., and L.M. Magnuson, 2003, Regional trends in coalbed gas composition and thermal maturation in eastern Kansas: implications for predicting quality and location of coalbed gas (abstract): AAPG Mid-Continent Section Meeting, Official Program Book, p.39. (Oklahoma Geology Notes, v. 63, p. 97)

Newell, K.D., and Lange, J.P., 2004, Analysis of Cherokee Group cuttings samples for gas content--Gene M. Bailey #12 Kimball (NE NE SW sec. 19-T.30S.-R.16E.), Wilson County, Kansas: Kansas Geological Survey Open-File Report 2004-50, 16p.

Newell, K.D., L.L. Brady, J.P. Lange, and T.R. Carr, 2002, Coalbed gas play emerges in eastern Kansas basins: Oil & Gas Journal, v. 100.52, p. 36-41.Newell, K.D., L.M. Magnuson, and G. Gagnon, 2004, Analysis of Kansas City, Marmaton and Cherokee Group core samples for gas content—Osborne Energy Rose Hill #1-6 (sec. 6-T.16S.-R.24E.) Miami County, Kansas: Kansas Geological Survey Open-File Report 2004-23, 32p.

Newell, K.D., T.R. Carr, and G. Gagnon, 2004, Analysis of Pleasanton, Marmaton, and Cherokee Group core samples for gas content—Osborn Energy #1-22 Smith (sec. 22-T.44N.-R.33W.), Cass County, Missouri: Kansas Geological Survey, Open-file Report 2004-51, 51p.Newell, K.D., T.R. Carr, and W.M. Brown, 2005, Eastern Kansas CBNG shows promise: American Oil & Gas Reporter, v. 48, no. 8, p. 135-138.Newell, R.G., and R.N. Stavins, 2000, Climate change and forest sinks — Factors affecting the costs of carbon sequestration: Journal of Environmental Economics and Management, v. 40, no. 3, p. 211-235.Newman, J., 1997, New approaches to detection and correction of suppressed vitrinite reflectance: Australian Petroleum Production and Exploration Association Journal, v. 37, p. 524-535.Newman, J., and N.A. Newman, 1982, Reflectance anomalies in Pike River coals: evidence of variability in vitrinite type, with implications for maturation studies and "Suggate rank": New Zealand Journal of Geology and Geophysics, v. 25, p. 233-243.Newman, J., and N.A. Newman, 1982, Reflectance anomalies in Pike River coals: evidence of variability in vitrinite type, with implications for maturation studies and "Suggate rank": New Zealand Journal of Geology and Geophysics, v. 25, p. 233-243.

Newman, J., J. Johnston, and P. Lake, 1992, Isorank variation in vitrinite chemistry - 2. sterane and triterpane maturity indicators (abstract): TSOP Abstracts and Program, v. 9, p. 79-82.

Newman, J., L.C. Price, and J.H. Johnston, 1994, Variations in source potential and maturation of New Zealand coals, based on relationships between conventional coal chemistry, Rock-Eval pyrolysis, and GCMS biomarkers (abstract): TSOP Abstracts and Program, v. 11, p. 66-69.

Newman, J., L.C. Price, and J.H. Johnston, 1997, Hydrocarbon source potential and maturation in Eocene New Zealand vitrinite-rich coals: insights from traditional coal analyses, and Rock-Eval and biomarker studies: Journal of Petroleum Geology, v. 20, p. 137-163.Newman, J., L.C. Price, and L.C. Johnston, 1997, Hydrocarbon source potential and maturation in Eocene New Zealand vitrinite-rich coals: Journal of Petroleum Geology, v. 20, p. 137-163.Ng, N., 1983, Optical microscopy of carbonaceous solid residues from coal hydrogenation: a classification: Journal of Microscopy, v. 132, pt. 3, p. 289-296.Ni, Y., J. Dai, C. Zou, F. Liao, Y. Shuai, and Y. Zhang, 2013, Geochemical characteristics of biogenic gases in China: International Journal of Coal Geology, v. 113, p. 76-87.

Nelson, M.I., and X.D. Chen, 2007, Survey of experimental work on the self-heating and spontaneous combustion of coal, in G.B. Stracher, ed., Geology of coal fires: case studies from around the world: GSA Reviews in Engineering Geology 18, p. 31-83.

Neuzil, S.G., Supardi, C.B. Cecil, J.S. Kane, and K. Soedjono, 1993, Inorganic geochemistry of domed peat in Indonesia and its implication for the origin of mineral matter in coal, in J.C. Cobb and C.B. Cecil, eds., Modern and ancient coal-forming environments: GSA Special Paper 286, p. 23-44.

Newell, K.D., and D. Grisafe, 2004, Density, ash content, and moisture content of selected eastern Kansas Pennsylvanian coals and shales: Kansas Geological Survey Open-File Report 2004-42. (http://www.kgs.ku.edu/PRS/publication/2004/OFR04_42/index.html)

Newell, K.D., and L.M. Magnuson, 2003, Regional trends in coalbed gas composition and thermal maturation in eastern Kansas: implications for predicting quality and location of coalbed gas: Kansas: Kansas Geological Survey Open-File Report 2003-58. ( http://www.kgs.ku.edu/PRS/publication/2003/ofr2003-58.pdf)

Newell, K.D., and R.L. Yoakum, 2010, Kansas coalbed methane, in D.F. Merriam, ed., New plays and ways: Kansas Geological Society, Kansas Oil and Gas Fields, v. 6, p. 105-128.Newell, K.D., and T.R. Carr, 2009, Coal-bed natural gas production and gas content of Pennsylvanian coal units in eastern Kansas, in T. Carr, T. D’Agostino, W. Ambrose, J. Pashin, and N.C. Rosen, eds., Unconventional energy resources: making the unconventional conventional: 29 th Annual GCSSEPM Foundation Bob F. Perkins Research Conference, CD-ROM, p. 353-387.

Newell, K.D., R.S. Sawin, and L.L. Brady, 2012, Natural gas from coal in eastern Kansas: Kansas Geological Survey, Public Information Circular 19, 4 p. http://www.kgs.ku.edu/Publications/pic19/PIC19.pdf Newell, K.D., T.A. Johnson, W.M. Brown, J.P. Lange, and T.R. Carr, 2004, Geological and geochemical factors influencing the emerging coalbed gas play in the Cherokee and Forest City Basins in eastern Kansas: Kansas Geological Survey Open-File Report 2004-17. (http://www.kgs.ku.edu/PRS/publication/2004/AAPG/Coalbed/P1-02.html)

Newman, J., C.J. Boreham, S.D. Ward, A.P. Murray, and A.A. Bal, 1999, Floral influences on the petroleum source potential of New Zealand coals, in M. Mastalerz, M. Glikson, and S.D. Golding, eds., Coalbed methane: Scientific, environmental and economic evaluation: Boston, Kluwer Academic Publishers, p. 461-492.

Newman, J., J.H. Johnston, and P.J. Lake, 1992, The influence of isorank variations in vitrinite chemistry on vitrinite reflectance and some sterane and triterpane maturation indicators, in 1991 New Zealand oil exploration conference proceedings, v. 2: Wellington, Ministry of Commerce, p. 336-350.Newman, J., J.H. Johnston, and P.J. Lake, 1992, The influence of isorank variations in vitrinite chemistry on vitrinite reflectance and some sterane and triterpane maturation indicators, in 1991 New Zealand oil exploration conference proceedings, v. 2: Wellington, New Zealand, The Publicity Unit, Crown Minerals Operations Group, Energy and Resources Division, Ministry of Commerce, p. 336-350.

Newman, J., L.C. Price, and J.H. Johnston, 1994, Variations in source potential and maturation of New Zealand coals, based on relationships between conventional coal chemistry, Rock-Eval pyrolysis, and GCMS biomarkers, in 1994 New Zealand Petroleum Conference Proceedings: Wellington, The Publicity Unit, p. 370-384.

Ni, Y., J. Dai, G. Zhu, S. Zhang, D. Zhang, J. Su, X. Tao, F. Liao, W. Wu, D. Gong, and Q. Liu, 2013, Stable hydrogen and carbon isotopic ratios of coal-derived and oil-derived gases: A case study in the Tarim Basin, NW China: International Journal of Coal Geology, v. 116-117, p. 302-313.

Nie, R.-S., Y.-F. Meng, J.-C. Guo, and Y.-L. Jia, 2012, Modeling transient flow behavior of a horizontal well in a coal seam: International Journal of Coal Geology, v. 92, p. 54-68.Nielsen, L.C., I.C. Bourg, and G. Sposito, 2012, Predicting CO2–water interfacial tension under pressure and temperature conditions of geologic CO2 storage: Geochimica et Cosmochimica Acta, v. 81, p. 28-38.

Nip, M., J.W. De Leeuw, and P.A. Schenck, 1988, The characterization of eight maceral concentrates by means of Curie point pyrolysis-gas chromatography and Curie point pyrolysis-gas chromatography-mass spectrometry: Geochimica et Cosmochimica Acta, v. 52, p. 637-648.Nip, M., J.W. de Leeuw, P.A. Schenck, W. Windig, H.L.C. Meuzelaar, and J.C. Crelling, 1989, A flash pyrolysis and petrographic study of cutinite from the Indiana paper coal: Geochimica et Cosmochimica Acta, v. 53, p. 671-683.Nishioka, M., 1992, The associated molecular nature of bituminous coal: Fuel, v. 71, p. 941.Nissenbaum, A., and M. Goldberg, 1980, Asphalts, heavy oils, ozocerite and gases in the Dead Sea basin: Organic Geochemistry, v. 2, p. 167-180.Nissenbaum, A., and Z. Aizenshtat, 1975, Geochemical studies on ozokerite from the Dead Sea area: Chemical Geology, v. 16, p. 121-127.Noak, K., 1998, Control of gas emissions in underground coal mines: International Journal of Coal Geology, v. 35, p. 57-82.Noble, R.A., C.H. Wu, and C.D. Atkinson, 1991, Petroleum generation and migration from Talang Akar coals and shales offshore N.W. Java, Indonesia: Organic Geochemistry, v. 17, p. 363-374.Nodzenski, A., 1998, Sorption and desorption of gases (CH4, CO2) on hard coal and active carbon at elevated pressures: Fuel, v. 77, p. 1243-1246.Noeth, S., R.O. Thomsen, and R. Littke, 2002, A method for assessing statistical significance and uncertainties for calibration of 1-D thermal basin maturation models: AAPG Bulletin, v. 86, p. 417-431. (Ro vs. depth)

Nomura, S., 2010, Behavior of coal chlorine in cokemaking process: International Journal of Coal Geology, v. 83, p. 423-429.Nomura, S., 2010, Behavior of coal chlorine in cokemaking process: International Journal of Coal Geology, v. 83, p. 423-429.Nomura, S., 2014, Behavior of chlorine during co-carbonization of coal and chloride compounds in cokemaking process: International Journal of Coal Geology, v. 130, p. 27-32.Nondorf, L., M. Gutierrez, and T.G. Plymate, 2011, Modeling carbon sequestration geochemical reactions for a proposed site in Springfield, Missouri: Environmental Geosciences Journal, v. 18, no. 2.Nordbotten, J.M., and M.A. Celia, 2012, Geological storage of CO2: modeling approaches for large-scale simulation: Hoboken, NJ, John Wiley & Sons, Inc., 241 p.Nowacki, P., ed., 1981, Oil shale technical data handbook: Park Ridge, N.J., Noyes Data Corporation, 309 p.Nowak, G.J., 2004, Facies studies of bituminous coals in Poland: International Journal of Coal Geology, v. 58, p. 61-66.

Nuccio, V.F., 2000, Coal-bed methane: potential and concerns: U.S. Geological Survey Fact Sheet FS-123-00.

Nuccio, V.F., and J.R. Hatch, 1996, Vitrinite reflectance suppression in the New Albany Shale, Illinois Basin; vitrinite reflectance and Rock-Eval data: U.S. Geological Survey Open-File Report 96-0665, 37 p.Nuccio, V.F., and R.C. Johnson, 1988, Surface vitrinite-reflectance map of the Uinta, Piceance, and Eagle basins area, Utah and Colorado: U.S. Geological Survey Map MF-2008-B.Nuccio, V.F., and R.C. Johnson, 1988, Surface vitrinite-reflectance map of the Uinta, Piceance, and Eagle basins area, Utah and Colorado: USGS Map MF-2008-B, 21 p., 1 plate (scale 1:500,000).Nuttall, B.C., 2007, Analysis of Devonian shale in eastern Kentucky for carbon sequestration possibilities: Energeia, v. 18, no. 3, p. 1-3.Nuttall, B.C., 2007, Analysis of Devonian shale in eastern Kentucky for carbon sequestration possibilities: Energeia, v. 18, no. 3, p. 1-3.Nuttall, B.C., C.F. Eble, J.A. Drahovzal, and R.M. Bustin, 2005, Analysis of Devonian black shales in Kentucky for potential carbon dioxide sequestration and enhanced natural gas production: Kentucky Geological Survey/University of Kentucky report, DE-FC26-02NT41442.Nuttall, B.C., J.A. Drahovzal, C.F. Eble, and R.M. Bustin, 2009, Regional assessment of organic-rich gas shales for carbon sequestration: an example from the Devonian shales of the Illinois and Appalachian basins, Kentucky: AAPG Studies in Geology, v. 59, p. 173-190.Nuttall, B.C., J.A. Drahovzal, C.F. Eble, and R.M. Bustin, 2009, Regional assessment of organic-rich gas shales for carbon sequestration: an example from the Devonian shales of the Illinois and Appalachian basins, Kentucky: AAPG Studies in Geology, v. 59, p. 173-190.Nyathi, M.S., M. Mastalerz, and R. Kruse, 2013, Influence of coke particle size on pore structural determination by optical microscopy: International Journal of Coal Geology, v. 118, p. 8-14.Nywlt, M., and S. Peter, 1992, Improvement of coal gasification—effect of salt dissolved in supercritical water: Erdöl und Kohle-Erdgas-Petrochemie, v. 45, p. 349-353.Nzoussi-Mbassani, P., Y. Copard, and J.R. Disnar, 2005, Vitrinite recycling: diagnostic criteria and reflectance changes during weathering and reburial: International Journal of Coal Geology, v. 61, p. 223-239.Nzoussi-Mbassani, P., Y. Copard, and J.R. Disnar, 2005, Vitrinite recycling: diagnostic criteria and reflectance changes during weathering and reburial: International Journal of Coal Geology, v. 61, p. 223-239.

Nicholls, G.D., 1968, The geochemstry of coal-bearing strata, in D. Murchison, and T.S. Westoll, eds., Coal and coal-bearing strata: New York, Elsevier, p. 269-308.Nichols, D.J., 2005, Palynology in coal systems analysis—the key to floras, climate, and stratigraphy of coal-forming environments, in P.D. Warwick, ed., Coal systems analysis: Geological Society of America Special Paper 387, p. 51-58.

Nikols, D.J., and B.A. Rottenfusser, 1991, Coalbed methane — a Canadian resource for the 1990s, in S.D. Schwochow, D.K. Murray, and M.F. Fahy, eds., Coalbed methane of western North America: Denver, Rocky Mountain Association of Geologists, p. 249-253.

Nohr-Hansen, H., 1989, Visual and chemical kerogen analyses of the Lower Kimmeridge Clay, Westbury, England, in D.J. Batten and M.C. Keen, eds., Northwest European micropalaeontology and palynology: New York, Halsted Press, p. 118-134.Nolde, J.E., and D. Spears, 1998, A preliminary assessment of in place coalbed methane resources in the Virginia portion of the central Appalachian basin, in P.C. Lyons, ed., Special issue: Appalachian coalbed methane: International Journal of Coal Geology, v. 38, p. 115-136.Nolter, M.A., D.H. Vice, and H. Aurand, Jr., 2007, Comparison of Pennsylvania anthracite mine fires: Centralia and Laurel Run, in G.B. Stracher, ed., Geology of coal fires: case studies from around the world: GSA Reviews in Engineering Geology 18, p. 261-270.

Nowak, H.C., 1991, Depositional environments and stratigraphy of Mesaverde Formation, southeastern Piceance Basin, Colorado—Implications for coalbed methane exploration, in S.D. Schwochow, D.K. Murray, and M.F. Fahy, eds., Coalbed methane of western North America: Denver, CO, Rocky Mountain Association of Geologists Guidebook, p. 1-20.Nowak, M.A., A.D. Paul, R.D. Sriastava, and A. Radziwon, 2004, Coal conversion, in Reference Module in Earth Systems and Environmental Sciences: Elsevier, Encyclopedia of Energy, v. 1, p. 425-434.

Nuccio, V.F., 2002, Coalbed methane — What is it? Where is it? And why all the fuss?, in S.D. Schwochow and V.F. Nuccio, eds., Coalbed methane of North America, II: Rocky Mountain Association of Geologists, p. 1-6.

Nzoussi-Mbassani, P., Y. Copard, and J.R. Disnar, 2005, Vitrinite recycling: diagnostic criteria and reflectance changes during weathering and reburial: International Journal of Coal Geology, v. 61, p. 223-239.O’Brien, N.R., R.M. Slatt, and J. Senftle, 1994, The significance of oil shale fabric in primary hydrocarbon migration: Fuel, v. 73, p. 1518-1522.O’Keefe, J.M.K., A. Bechtel, K. Christanis, S. Dai, W.A. DiMichele, C.F. Eble, J.S. Esterle, M. Mastalerz, A.L. Raymond, B.V. Valentim, N.J. Wagner, C.R. Ward, and J.C. Hower, 2013, On the fundamental difference between coal rank and coal type: International Journal of Coal Geology, v. 118, p. 58-87.O’Keefe, J.M.K., A. Bechtel, K. Christanis, S. Dai, W.A. DiMichele, C.F. Eble, J.S. Esterle, M. Mastalerz, A.L. Raymond, B.V. Valentim, N.J. Wagner, C.R. Ward, and J.C. Hower, 2013, On the fundamental difference between coal rank and coal type: International Journal of Coal Geology, v. 118, p. 58-87.O’Keefe, J.M.K., and C.F. Eble, 2012, A comparison of HF-based and non-HF-based palynology processing techniques in clay-rich lignites from the Claiborne Group, upper Mississippi Embayment, United States: Palynology, v. 36, no. 1, p. 116-130.O’Keefe, J.M.K., and J.C. Hower, 2011, Revisiting Coos Bay, Oregon: a re-examination of funginite-huminite relationships in Eocene subbituminous coals: International Journal of Coal Geology, v. 85, p. 34-42.O’Keefe, J.M.K., E.R. Neace, E.W. Lemley, J.C. Hower, K.R. Henke, G. Copley, R.S. Hatch, A.B. Satterwhite, and D.R. Blake, 2011, Old Smokey coal fire, Floyd County, Kentucky: Estimates of gaseous emission rates: International Journal of Coal Geology, v. 87, p. 150-156.O’Keefe, J.M.K., J.C. Hower, R.F. Finkelman, J.W. Drew, and J.D. Stucker, 2011, Petrographic, geochemical, and mycological aspects of Miocene coals from the Nováky and Handlová mining districts, Slovakia: International Journal of Coal Geology, v. 87, p. 268-281. (funginite)O’Keefe, J.M.K., J.C. Hower, R.F. Finkelman, J.W. Drew, and J.D. Stucker, 2011, Petrographic, geochemical, and mycological aspects of Miocene coals from the Nováky and Handlová mining districts, Slovakia: International Journal of Coal Geology, v. 87, p. 268-281. (funginite)O’Niel, P.E., S.C. Harris, M.F. Mettee, T.E. Shepard, and S.W. McGregor, 1993, Surface discharge of wastewaters from the production of methane from coal seams in Alabama, the Cedar Cove model: Alabama Geological Survey Bulletin 155, 259 p.O’Niel, P.E., S.C. Harris, M.F. Mettee, T.E. Shepard, and S.W. McGregor, 1993, Surface discharge of wastewaters from the production of methane from coal seams in Alabama, the Cedar Cove model: Alabama Geological Survey Bulletin 155, 259 p.O’Sullivan, R.B., and T.G. Ging, 1988, Preliminary report on solid bitumens in Eocene rocks of Piceance Creek basin, northwestern Colorado: U.S. Geological Survey, Open-File Report 87-0478, 13 p.Obaje, N.G., and H. Hamza, 2000, Liquid hydrocarbon source-rock potential of mid-Cretaceous coals and coal measures in the middle Benue trough of Nigeria: International Journal of Earth Sciences, v. 89, p. 130-139.Obaje, N.G., H. Wehner, G. Scheeder, M.B. Abubakar, and A. Jauro, 2004, Hydrocarbon prospectivity of Nigeria’s inland basins: from the viewpoint of organic geochemistry and organic petrology: AAPG Bulletin, v. 88, p. 325-353.Obermajer, M., L.D. Stasiuk, M.G. Fowler, and K.G. Osadetz, 1999, Application of acritarch fluorescence in thermal maturity studies: International Journal of Coal Geology, v. 39, p. 185-204.Obermajer, M., M.G. Fowler, and L.R. Snowdon, 1999, Depositional environment and oil generation in Ordovician source rocks from southwestern Ontario, Canada: organic geochemical and petrological approach: AAPG Bulletin, v. 83, p. 1426-1453.Obermajer, M., M.G. Fowler, F. Goodarzi, and L.R. Snowdon, 1996, Assessing thermal maturity of Palaeozoic rocks from reflectance of chitinozoa as constrained by geochemical indicators: an example from southern Ontario, Canada: Marine and Petroleum Geology, v. 13, p. 907-919.Oelkers, E.H., and D.R. Cole, 2008, Carbon dioxide sequestration: a solution to a global problem: Elements, v. 4, p. 305-310.Oelkers, E.H., S.R. Gislason, and J. Matter, 2008, Mineral carbonation of CO2: Elements, v. 4, p. 333-337.Oesterlen, P.M., and J. Lepper, 2005, The Lower Karoo coal (K2-3) of the Mid-Zambezi Basin, Zimbabwe: depositional analysis, coal genesis and palaeogeographic implications: International Journal of Coal Geology, v. 61, p. 97-118.Ogbe, D.O., J.B. Packer, and J.G. Clough, 2002, Risk-weighted volumetric analysis to estimate gas reserves and evaluate coalbed methane potential of the Lower matanuska valley, Cook Inlet basin, Alaska (abstract): AAPG Bulletin, v. 86, p. 1155-1156.

Ogunyami, O., R. Hesse, and Y. Heroux, 1980, Pre-orogenic and synorogenic diagenesis and anchimetamorphism in lower Paleozoic continental margin sequences of the northern Appalachians in and around Quebec City, Canada: Bulletin of Canadian Petroleum Geology, v. 28, p. 559-577.Ohm, S.E., and D.A. Karlsen, 2007, Biogenic gas (?) in fluid inclusions from sandstones in contact with oil-mature coals: AAPG Bulletin, v. 91, p. 715-739.Oil & Gas Journal, 2003, Coiled-tubing fracturing effectively stimulates multiple coal seams: Oil & Gas Journal, v. 101.10, p. 47-48.Oka, N., T. Murayama, H. Matsuoka, S. Yamada, T. Yamada, S. Shinozaki, M. Shibaoka, and C.G. Thomas, 1987, The influence of rank and maceral composition on ignition and char burnout of pulverized coal: Fuel Processing Technology, v. 15, p. 213-224.Okada, K., 1991, Maceral analysis of coals by image processing: Journal of Coal Quality, v. 10, p. 12-19.

Okuszko, K., and B. Gault, 2007, Analyze CBM decline performance: Hart’s E&P, v. 80, no. 6, p. 99-101.Okuyama, Y., N. Todaka, M. Sasaki, S. Ajima, and C. Akasaka, 2013, Reactive transport simulation study of geochemical CO2 trapping on the Tokyo Bay model—With focus on the behavior of dawsonite: Applied Geochemistry, v. 30, p. 57-66.Olague, N.E., and D.M. Smith, 1989, Diffusion of gases in American coals: Fuel, v. 68, p. 1381-1387.

Olea, R.A., and J.A. Luppens, 2012, Sequential simulation approach to modeling of multi-seam coal deposits with an application to the assessment of a Louisiana lignite: Natural Resources Research, v. 21, p. 443-459.Olea, R.A., J.A. Luppens, and S.J. Tewalt, 2011, Methodology for quantifying uncertainty in coal assessments with an application to a Texas lignite deposit: International Journal of Coal Geology, v. 85, p. 78-90.Olierook, H.K.H., C. Delle Piane, N.E. Timms, L. Esteban, R. Rezaee, A.J. Mory, and L. Hancock, 2014, Facies-based rock properties characterization for CO2 sequestration: GSWA Harvey 1 well, western Australia: Marine and Petroleum Geology, v. 50, p. 83-102.Oliveira, M.L.S., C.R. Ward, C.H. Sampaio, X. Querol, C.M.N.L. Cutruneo, S.R. Taffarel, and L.F.O. Silva, 2013, Partitioning of mineralogical and inorganic geochemical components of coals from Santa Catarina, Brazil, by industrial beneficiation processes: International Journal of Coal Geology, v. 116-117, p. 75-92.Oliveira, M.L.S., C.R. Ward, D. French, J.C. Hower, X. Querol, and L.F.O. Silva, 2012, Mineralogy and leaching characteristics of beneficiated coal products from Santa Catarina, Brazil: International Journal of Coal Geology, v. 94, p. 314-325.Oliveira, M.L.S., C.R. Ward, D. French, J.C. Hower, X. Querol, and L.F.O. Silva, 2012, Mineralogy and leaching characteristics of beneficiated coal products from Santa Catarina, Brazil: International Journal of Coal Geology, v. 94, p. 314-325.

Ogo, Y., and Y. Miyamoto, 1987, Donor-solvent liquefaction of Morwell and Illinois No. 6 coals up to 60 MPa pressure, in J.A. Moulijn, ed., 1987 International Conference on Coal Science: New York, Academic Press, p. 219-222.

Okada, K., 1995, Possible impacts of coal properties on the coal conversion technology, in J.A. Pajares and J.M.D. Tascon, eds., Coal science: New York, Elsevier, Coal Science and Technology 24, v. 2, p. 1247-1250.

Oldaker, P.R., 1991, Hydrogeology of the Fruitland Formation, San Juan basin, Colorado and New Mexico, in S.D. Schwochow, D.K. Murray, and M.F. Fahy, eds., Coalbed methane of western North America: Denver, Rocky Mountain Association of Geologists, p. 61-66.

Oliver, G.J.H., 1988, Arenig to Wenlock regional metamorphism in the paratectonic Caledonides of the British Isles: a review, in A.L. Harris and D.J. Fettes, eds., The Caledonian-Appalachian Orogen: London, The Geological Society, Special Publication 38, Blackwell Scientific Publications, p. 347-363.Oliver, R.L., and G.F. "Pete" Dana, 1991, Underground coal gasification, in D.C. Peters, ed., Geology of coal resource utilization: Fairfax, VA, Techbooks, p. 155-168.Oliver, R.L., and G.F. Dana, 1991, Underground coal gasification, in D.C. Peters, ed., Geology in coal resource utilization: Fairfax, Va., Techbooks, p. 155-168. (available through AAPG)

Oliver, S., 2002, Methane enrichment: World Coal, v. 11, p. 53-55.Oliver, S., 2002, Methane enrichment: World Coal, v. 11, p. 53-55. (CMM)Olson, M., T. Smith, and B. Fehn, 2004, Optimized flow device eliminates CBM lift equipment, reduces costs: World Oil, v. 225, no. 5, p. 70-71.Olsson, J., N. Bovet, E. Makovicky, K. Bechgaard, Z. Balogh, and S.L.S. Stipp, 2012, Olivine reactivity with CO2 and H2O on a microscale: Implications for carbon sequestration: Geochimica et Cosmochimica Acta, v. 77, p. 86-97.Olszewski, A.J., and R.A. Schraufnagel, 1992, Development of formation evaluation technology for coalbed methane development: Quarterly Review of Methane from Coal Seams Technology, v. 10, no. 2, p. 29-35; v. 10, no. 3, p. 32-36.Opara, A., D.J. Adams, M.L. Free, J. McLennan, and J. Hamilton, 2012, Microbial production of methane and carbon dioxide from lignite, bituminous coal, and coal waste materials: International Journal of Coal Geology, v. 96-97, p. 1-8. (biogenic methane)Opera, A., B. Alizadeh, H. Sarafdokht, M. Janbaz, R. Fouladvand, and M.H. Heidarifard, 2013, Burial history reconstruction and thermal maturity modeling for the Middle Cretaceous–Early Miocene petroleum system, southern Dezful Embayment, SW Iran: International Journal of Coal Geology, v. 120, p. 1-14.Oplustil, S., 2005, The effect of paleotopography, tectonics and sediment supply on quality of coal seams in continental basins of central and western Bohemia (Westphalian), Czech Republic: International Journal of Coal Geology, v. 64, p. 173-203.Opluštil, S., N.A. Edress, and I. Sýkorová, 2013, Climatic vs. tectonic controls on peat accretion in non-marine setting; an example from the Žacléř Formation (Yeadonian-Bolsovian) in the Intra-Sudetic Basin (Czech Republic): International Journal of Coal Geology, v. 116-117, p. 135-157.Opsahl, S., and R. Benner, 1995, Early diagenesis of vascular plant tissues: lignin and cutin decomposition and biochemical implications: Geochimica et Cosmochimica Acta, v. 59, p. 4889-4904.Orange, D.L., and M.B. Underwood, 1995, Patterns of thermal maturity as diagnostic criteria for interpretation of melanges: Geology, v. 23, p. 1144-1148.Orem, W., C. Tatu, M. Varonka, H. Lerch, A. Bates, M. Engle, L. Crosby, and J. McIntosh, 2014, Organic substances in produced and formation water from unconventional natural gas extraction in coal and shale: : International Journal of Coal Geology, v. 126, p. 20-31.Orem, W.H., C.A. Tatu, H.E. Lerch, C.A. Rice, T.T. Bartos, A.L. Bates, S. Tewalt, and M.D. Corum, 2007, Organic compounds in produced waters from coalbed natural gas wells in the Powder River Basin, Wyoming, USA: Applied Geochemistry, v. 22, p. 2240-2256.Orem, W.H., S.G. Neuzil, H.E. Lerch, and C.B. Cecil, 1996, Experimental early-stage coalification of a peat sample and a peatified wood sample from Indonesia: Organic Geochemistry, v. 24, p. 111-125.

Orr, W.L., 1986, Kerogen/asphaltene/sulfur relationships in sulfur-rch Monterey oils: Organic Geochemistry, v. 10, p. 499-516.

Osório, E., M. de Lourdes Ilha Gomes, A.C.F. Vilela, W. Kalkreuth, M.A.A. de Almeida, A.G. Borrego, and D. Alvarez, 2006, Evaluation of petrology and reactivity of coal blends for use in pulverized coal injection (PCI): International Journal of Coal Geology, v. 68, p. 14-29.Othman, R., and C.R. Ward, 2002, Thermal maturation pattern in the southern Bowen, northern Gunnedah and Surat basins, northern New South Wales, Australia: International Journal of Coal Geology, v. 51, p. 145-167.Othman, R., and C.R. Ward, 2002, Thermal maturation pattern in the southern Bowen, northern Gunnedah and Surat basins, northern New South Wales, Australia: International Journal of Coal Geology, v. 51, p. 145-167.(influence of marine)Othman, R., K.R. Arouri, C.R. Ward, and D.M. KcKirdy, 2001, Oil generation by igneous intrusions in the northern Gunnedah basin, Australia: Organic Geochemistry, v. 32, p. 1219-1232.Ots, A., 2004, Oil shale combustion technology: Oil Shale, v. 21, p. 149-160.Ottenjann, K., 1983, Improved microphotometric fluorescence measurements of coal macerals: Zeiss Information, v. 26, no. 93, p. 40-46.Ottenjann, K., 1988, Fluorescence alteration and its value for studies of maturation and bituminization: Organic Geochemistry, v. 12, p. 309-321.Ottenjann, K., 1992, An alternative method for measurements of maximum reflectance of coal constituents: Zeiss Information, v. 31, no. 103, p. 45-48.

Ouchi, K., S. Ibaragi, A. Kobayashi, K. Makino, and H. Itoh, 1984, Reactivity of coals in hydrogenation: Fuel, v. 63, p. 427-430.Ouchi, K., S. Ibaragi, A. Kobayashi, K. Tanimoto, M. Madabe, H. Itoh, K. Matsubara, and T. Takekawa, 1984, Effect of blending on liquefaction of coals: Fuel, v. 63, p. 78-83.Ouyang, Z., J. Zhu, Q. Lu, Y. Yao, and J. Liu, 2014, The effect of limestone on SO2 and NOx emissions of pulverized coal combustion preheated by circulating fluidized bed: Fuel, v. 120, p. 116-121.Owsiacki, G., and G. Payie, 2000, Coalbed methane potential in British Columbia: British Columbia Ministry of Energy and Mines, GeoFile 2000-7, 44 p.Oyama, T., and M. Chigira, 2000, Weathering rate of mudstone and tuff on old unlined tunnel walls: Engineering Geology, v. 55, p. 15-27.Oygard, K., S. Larter, and J. Senftle, 1988, The control of maturity and kerogen type on quantitative analytical pyrolysis data: Organic Geochemistry, v. 13, p. 1153-1162.Oyler, D.C., and R.B. Stubbs, 1985, Measuring formation pressures and the degree of gas drainage in a large coalbed gas drainage field: U.S. Bureau of Mines Report of Investigations 8986, 15 p.Oyler, D.C., and W.P. Diamond, 1982, Drilling a horizontal coalbed methane drainage system from a directional surface borehole: U.S. Bureau of Mines Report of Investigations 8640, 50 p.Oyler, D.C., W.P. Diamond, and P.W. Jeran, 1979, Directional drilling for coalbed degasification: U.S. Bureau of Mines Report of Investigations 8380, 15 p.Ozdemir, E., 2009, Modeling of coal bed methane (CBM) production and CO2 sequestration in coal seams: International Journal of Coal Geology, v. 77, p. 145-152.Ozdemir, E., B.I. Morsi, and K. Schroeder, 2004, CO2 adsorption capacity of Argonne premium coals: Fuel, v. 83, p. 1085-1094.Özgen Karacan, C., and K. Luxbacher, 2010, Stochastic modeling of gob gas venthole production performances in active and completed longwall panels of coal mines: International Journal of Coal Geology, v. 84, p. 125-140.Özgen Karacan, C., F.A. Ruiz, M. Cotè, and S. Phipps, 2011, Coal mine methane: A review of capture and utilization practices with benefits to mining safety and to greenhouse gas reduction: International Journal of Coal Geology, v. 86, p. 121-156.Packham, R., L. Connell, Y. Cinar, and R. Moreby, 2012, Observations from an enhanced gas recovery field trial for coal mine gas management: International Journal of Coal Geology, v. 100, p. 82-92.

Orr, W.L., 1983, Comments on pyrolytic hydrocarbon yields in source-rock evaluation, in M. Bjoroy and others, eds., Advances in organic geochemistry 1981: John Wiley & Sons, Ltd., p. 775-787.

Osborne, T. E., 1997, Stratigraphy and structure of sections 1 and 12, T. 16 S., R. 3 E., of the Coal City Basin within the Coosa synclinorium of Alabama, in D.N. Bearce, J. C. Pashin, and W. E. Osborne, eds., Geology of the Coosa Coalfield: Alabama Geological Society 34th Annual Field Trip Guidebook, p. 39-49.Osborne, T.E., D.K. Moore, J.T. Kidd, and F.T. Pescatore, Jr., 1991, Coalbed methane potential of the northern Coosa basin in Alabama, in R.B. Finkelman and D.C. Peters, eds., Practical applications of coal geology: Journal of Coal Quality, v. 10, p. 95-103.

Ottenjann, K., M. Teichmüller, and M. Wolf, 1975, Spectral fluorescence measurements of sporinites in reflected light and their applicability for coalfication studies, in B. Alpern, ed., Petrographie de la matiere organique des sediments, relations avec la paleotemperature et le potential petrolier: Paris, CNRS, p. 49-65.

Packham, R., Y. Cinar, and R. Moreby, 2011, Simulation of an enhanced gas recovery field trial for coal mine gas management: International Journal of Coal Geology, v. 85, p. 247-256.Pacton, M., G.E. Gorin, and C. Vasconcelos, 2011, Amorphous organic matter—Experimental data on formation and the role of microbes: Review of Palaeobotany and Palynology, v. 166, p. 253-267.Padgett, J.T., 1980, The nature and occurrence of pseudovitrinite in the Herrin (No. 6) coal seam of southern Illinois: Carbondale, Southern Illinois University, unpublished M.S. thesis, 133 p.Padgett, P.L., S.M. Rimmer, J.C. Ferm, J.C. Hower, C.F. Eble, and M. Mastalerz, 1999, Sulfur variability and petrology of the Lower Block coal member (Pennsylvanian) in southwest Indiana: International Journal of Coal Geology, v. 39, p. 97-120.Padgett, P.L., S.M. Rimmer, J.C. Ferm, J.C. Hower, C.F. Eble, and M. Mastalerz, 1999, Sulfur variability and petrology of the Lower Block coal member (Pennsylvanian) in southwest Indiana: International Journal of Coal Geology, v. 39, p. 97-120.Padula, V.T., 1969, Oil shale of Permian Irati Formation: AAPG Bulletin, v. 53, p. 591-602.Painter, P.C., M.M. Coleman, R.W. Snyder, O. Mahajan, M. Komatsu, and P.L. Walker, Jr., 1981, Low temperature air oxidation of caking coals: Fourier transform infrared studies: Applied Spectroscopy, v. 35, p. 106-110.Painter, P.C., R.W. Snyder, D.E. Pearson, and J. Kwong, 1980, Fourier transform infrared study of the variation in the oxidation of a coking coal: Fuel, v. 59, p. 282-286.Pajak, J., 1993, Reactivity of coal macerals. Hydrogen transfer reaction fro tetrahydrothiophene: Erdol und Kohle-Erdgas-Petrochemie, v. 46, p. 153-155.Pajares, J.A., and J.M.D. Tascon, eds., 1995, Coal science (2 volumes): New York, Elsevier, Coal Science and Technology, v. 24, 2017 p.

Palmer, C.A., and P.C. Lyons, 1996, Selected elements in major minerals from bituminous coals as determined by INAA: implications for removing environmentally sensitive elements from coal: International Journal of Coal Geology, v. 32, p. 151-166.Palmer, C.A., ed., 1997, The chemical analysis of Argonne Premium Coal samples: U.S. Geological Survey Bulletin 2144, 106 p.Palmer, C.A., ed., 1997, The chemical analysis of Argonne Premium Coal samples: U.S. Geological Survey Bulletin 2144, 106 p.Palmer, C.A., M.R. Krasnow, R.B. Finkelman, and W.M. D’Angelo, 1993, An evaluation of leaching to determine modes of occurrence of selected toxic elements in coal: Journal of Coal Quality, v. 12, p. 135-141.Palmer, C.A., M.R. Krasnow, R.B. Finkleman, and W.M. D’Angelo, 1993, An evaluation of leaching to determine modes of occurrence of selected toxic elements in coal: Journal of Coal Quality, v. 12, p. 135-141.

Palmer, I., 2009, Permeability changes in coal: Analytical modeling: International Journal of Coal Geology, v. 77, p. 119-126.Palmer, I., 2010, Coalbed methane completions: a world view: International Journal of Coal Geology, v. 82, p. 184-195.

Palmer, I.D., J.R. Cameron, and Z.A. Moschovidis, 2005, Looking for permeability loss or gain during coalbed methane production: 2005 International Coalbed Methane Symposium, Tuscaloosa, AL, Paper 0515, 19 p.Palmer, I.D., J.R. Cameron, and Z.A. Moschovidis, 2006, Permeability changes affect CBM production predictions: Oil & Gas Journal, v. 104.28, p. 43-50.

Pan, J., Q. Hou, Y. Ju, H. Bai, and Y. Zhao, 2012, Coalbed methane sorption related to coal deformation structures at different temperatures and pressures: Fuel, v. 102, p. 760-765.Pan, Z., and L. Connell, 2007, A theoretical model for gas adsorption-induced coal swelling: International Journal of Coal Geology, v. 69, p. 243-252.Pan, Z., and L. Connell, 2007, A theoretical model for gas adsorption-induced coal swelling: International Journal of Coal Geology, v. 69, p. 243-252. Pan, Z., and L.D. Connell, 2011, Modelling of anisotropic coal swelling and its impact on permeability behavior for primary and enhanced coalbed methane recovery: International Journal of Coal Geology, v. 85, p. 257-267.Pan, Z., and L.D. Connell, 2011, Modelling of anisotropic coal swelling and its impact on permeability behavior for primary and enhanced coalbed methane recovery: International Journal of Coal Geology, v. 85, p. 257-267.Pan, Z., and L.D. Connell, 2012, Modelling permeability for coal reservoirs: A review of analytical models and testing data: International Journal of Coal Geology, v. 92, p. 1-44.Pan, Z., and L.D. Connell, 2012, Modelling permeability for coal reservoirs: A review of analytical models and testing data: International Journal of Coal Geology, v. 92, p. 1-44.Pan, Z., L.D. Connell, and M. Camilleri, 2010, Laboratory characterization of coal reservoir permeability for primary and enhanced coalbed methane recovery: International Journal of Coal Geology, v. 82, p. 252-261.Pan, Z., L.D. Connell, and M. Camilleri, 2010, Laboratory characterization of coal reservoir permeability for primary and enhanced coalbed methane recovery: International Journal of Coal Geology, v. 82, p. 252-261.Pan, Z., L.D. Connell, M. Camilleri, and L. Connelly, 2010, Effects of matrix moisture on gas diffusion and flow in coal: Fuel, v. 89, p. 3207-3217.Pan, Z., L.D. Connell, M. Camilleri, and L. Connelly, 2010, Effects of matrix moisture on gas diffusion and flow in coal: Fuel, v. 89, p. 3207-3217.Panaitescu, C., and G. Predeanu, 1999, Carbopetrographic atlas: Coals, coke, carbon products: Editura Academiei Române, Bucaresti, România, ISBN 973-27-0724-0, 264 p.Panaitescu, C., and G. Predeanu, 2007, Microstructural characteristics of toluene and quinoline-insolubles from coal-tar pitch and their cokes: International Journal of Coal Geology, v. 71, p. 448-454.

Papendick, S.L., K.R. Downs, K.D. Vo, S.K. Hamilton, G.K.W. Dawson, S.D. Golding, and P.C. Gilcrease, 2011, Biogenic methane potential for Surat Basin, Queensland coal seams: International Journal of Coal Geology, v. 88, p. 123-134.

Palacas, J.G., D.E. Anders, J.K. King, and C.M. Lubeck, 1989, Use of biological markers in determining thermal maturity of biodegraded heavy oils and solid bitumens, in R.F. Meyer, ed., and others, International Conference on Heavy Crude and Tar Sands: Fourth UNITAR/UNDP International Conference on Heavy Crude and Tar Sands, v. 2, p. 575-592.

Palmer, I. D., 2004, Permeability changes in a CBM reservoir during production: an update and implications for CO 2 injection: Tuscaloosa, Alabama, University of Alabama, College of Continuing Studies, 2004 International Coalbed Methane Symposium Proceedings, paper 0403, 25 p.Palmer, I., 2009, Getting natural gas out of shales and coals, in T. Carr, T. D’Agostino, W. Ambrose, J. Pashin, and N.C. Rosen, eds., Unconventional energy resources: making the unconventional conventional: 29 th Annual GCSSEPM Foundation Bob F. Perkins Research Conference, CD-ROM, p. 306-328.

Palmer, I.D., and D.P. Sparks, 1992, Measurement of induced fractures by downhole TV camera in Black Warrior basin coalbeds, in Coalbed methane: Society of Petroleum Engineers, Reprint Series 35, p. 167-175.

Palmer, I.D., M.W. Davids, and S.J. Leu, 1992, Analysis of unconventional behavior observed during coalbed fracturing treatments, in Coalbed methane: Society of Petroleum Engineers, Reprint Series 35, p. 176-196.Palmer, I.D., S.W. Lambert, and J.L. Spitler, 1993, Coalbed methane well completions and stimulations, in B.E. Law and D.D. Rice, eds., Hydrocarbons from coal: AAPG Studies in Geology 38, p. 303-339.Palmer, S.R., E.J. Hippo, M.A. Kruge, and J.C. Crelling, 1990, Characterization of organic sulfur compounds in coals and coal macerals, in W.L. Orr and C.M. White, eds., Geochemistry of sulfur in fossil fuels: Washington, D.C., American Chemical Society Symosium Series 429, p. 296-315.

Pandolfo, A.G., A.S. Buchanan, and R.B. Johns, 1995, Chemical changes occurring during aerial oxidation of a bituminous coal, in J.A. Pajares and J.M.D. Tascon, eds., Coal science: Amsterdam, Elsevier Science, p. 477-480.

Papp, A.R., J.C. Hower, and D.C. Peters, 1998, Atlas of coal geology: American Association of Petroleum Geologists Studies in Geology 45, CD-ROM.

Pardo-Igúzquiza, E., P.A. Dowd, J.M. Baltuille, and M. Chica-Olmo, 2013, Geostatistical modeling of a coal seam for resource risk assessment: International Journal of Coal Geology, v. 112, p. 134-140.Pareek, H.S., 1988, Petrographic characteristics of the solid fuels of India with particular reference to the coking coals: International Journal of Coal Geology, v. 10, p. 285-307.Parekh, B.K., and J.G. Groppo, eds., 1993, Proceedings of the fifth international conference on processing and utilization of high-sulfur coals: Coal Science and Technology, v. 21, 638 p.Parkash, S., A.R. Cameron, and M.P. du Plessis, 1983, Application of coal petrography in the liquefaction of subbituminous coals and lignites: Alberta Research Council, Information Series 102, 30 p.Parkash, S., B. Ignasiak, M.P. du Plessis, and A.R. Cameron, 1983, Management of coal macerals in the liquefaction of low-rank coals: Liquid Fuels Technology, v. 1, p. 219-233.Parkash, S., K. Lali, M. Moluszko, and M.P. du Plessis, 1984, Contribution of vitrinite macerals to the liquefaction of subbituminous coals: Fuel Processing Technology, v. 9, p. 139-148.Parkash, S., K. Lali, M. Moluszko, and M.P. du Plessis, 1985, Separation of macerals from subbituminous coals and their response to liquefaction: Liquid Fuels Technology, v. 3, p. 345-375.Parkash, S., K. Nesbitt, and K. Lali, 1986, Fluorescence microscopical rank studies on sporinites (liptinite maceral) in Alberta coals: Journal of Coal Quality, v. 5, no. 1, p. 22-29.Parkash, S., M.P. du Plessis, A.R. Cameron, and W.D. Kalkreuth, 1984, Petrography of low rank coals with reference to liquefaction potential: International Journal of Coal Geology, v. 4, p. 209-234.Parkash, S., M.P. Du Plessis, A.R. Cameron, and W.D. Kalkreuth, 1984, Petrography of low rank coals with reference to liquefaction potential: International Journal of Coal Geology, v. 4, p. 209-234.

Parks, B.C., and H.J. O’Donnell, 1956, Petrography of American coals: U.S. Bureau of Mines Bulletin 550, 193 p.Parks, B.C., and H.J. O’Donnell, 1956, Petrography of American coals: U.S. Bureau of Mines Bulletin 550, 193 p.Parnell, J., 1988, Metal enrichments in solid bitumens: a review: Mineralium Deposita, v. 23, p. 191-199.Parnell, J., 1989, Hydrocarbon potential of lower Paleozoic of the British Isles: Oil & Gas Journal, v. 87, no. 32, p. 82-86.Parnell, J., and P.F. Carey, 1995, Emplacement of bitumen (asphaltite) veins in the Neuquen basin, Argentina: AAPG Bulletin, v. 79, p. 1798-1816.Parnell, J., B. Monson, and A. Geng, 1996, Maturity and petrography of bitumens in the Carboniferous of Ireland: International Journal of Coal Geology, v. 29, p. 23-38.Parnell, J., G. Ansong, F. Jiamo, and S. Guoying, 1994, Geology and geochemistry of bitumen vein deposits at Ghost City, Junggar basin, northwest China: Geological Magazine, v. 131, p. 181-190.Parnell, J., M. Baron, P. Mann, and P. Carey, 2003, Oil migration and bitumen formation in a hydrothermal system, Cuba: Journal of Geochemical Exploration, v. 78-79, p. 409-415.Pashin J. C., and R. E. Carroll, eds., 1999, Geology of the Cahaba coalfield: Alabama Geological Society 36th Annual Field Trip Guidebook, 98 p.Pashin, J. C., 1997, Productivity of coalbed methane wells in Alabama: Tuscaloosa, Alabama, University of Alabama, College of Continuing Studies, 1997 International Coalbed Methane Symposium Proceedings, p. 65-74.Pashin, J. C., 2005, Coalbed methane exploration in thrust belts: experience from the southern Appalachians, USA: Tuscaloosa, Alabama, University of Alabama, College of Continuing Studies, 2005 International Coalbed Methane Symposium Proceedings, Paper 0519, 14 p.

Pashin, J. C., and D. E. Raymond, 2004, Glacial-eustatic control of coalbed methane reservoir distribution (Pottsville Formation; Lower Pennsylvanian) in the Black Warrior Basin of Alabama: Tuscaloosa, Alabama, University of Alabama College of Continuing Studies, 2004 International Coalbed Methane Symposium Proceedings, Paper 0413, 15 p.

Pashin, J. C., G. Jin, and J. W. Payton, 2004, Three-dimensional computer models of natural and induced fractures in coalbed methane reservoirs of the Black Warrior Basin: Alabama Geological Survey Bulletin 174, 62 p.Pashin, J. C., R. E. Carroll, J. R. Hatch, and M. B. Goldhaber, 1999, Interplay among cleating, maturation, and mineralization in coalbed methane reservoirs of the Black Warrior Basin: Tuscaloosa, Alabama, University of Alabama, College of Continuing Studies, 1999 International Coalbed Methane Symposium Proceedings, p. 367-375.

Pashin, J., 2007, Hydrodynamics of coalbed methane reservoirs in the Black Warrior Basin: key to understanding reservoir performance and environmental issues: Applied Geochemistry, v. 22, p. 2257-2272.Pashin, J.C., 1994, Coal-body geometry and synsedimentary detachment folding in Oak Grove coalbed methane field, Black Warrior basin, Alabama: AAPG Bulletin, v. 78, p. 960-980.

Pashin, J.C., 2010, Variable gas saturation in coalbed methane reservoirs of the Black Warrior Basin: implications for exploration and production: International Journal of Coal Geology, v. 82, p. 135-146.Pashin, J.C., and F. Hinkle, 1997, Coalbed methane in Alabama: Alabama Geological Survey, Circular 192, 71 p.

Papp, A.R., J.C. Hower, and D.C. Peters, 2012, Atlas of coal geology (2nd edition): American Association of Petroleum Geologists Discovery Series 17, CD-ROM.Pappajohn, S.P., and T.E. Mitchell, 1991, Delineation of prospective coalbed methane trends in western and central Washington state, in S.D. Schwochow, D.K. Murray, and M.F. Fahy, eds., Coalbed methane of western North America: Denver, CO, Rocky Mountain Association of Geologists Guidebook, p. 163-178.

Parks, B.C., 1952, Mineral matter in coal, in Second conference on the origin and constitution of coal: Nova Scotia Department of Mines, p. 272-292.

Pashin, J. C., 2010, Mature coalbed natural gas reservoirs and operations in the Black Warrior basin of Alabama, in K.J. Reddy, ed., Coalbed natural gas: energy and environment: Haupage, New York, Nova Science Publishers, p. 31-57.

Pashin, J. C., and R. M. Mink, 1992, Pennsylvanian coalbed methane—Alabama, in D.G. Bebout, W. A. White, C. M. Garrett, Jr., and T. F. Henz, eds., Atlas of major central and eastern Gulf Coast gas reservoirs: Austin, Texas, Gas Research Institute and Texas Bureau of Economic Geology, p. 82-83.

Pashin, J. C., R. E. Carroll, R. H. Groshong, Jr., D. E. Raymond, M. R. McIntyre, and J. W. Payton, 2004, Geologic screening criteria for sequestration of CO 2 in coal: quantifying potential of the Black Warrior coalbed methane fairway, Alabama: Final Technical Report, U.S. Department of Energy, National Technology Laboratory, contract DE-FC26-00NT40927, 254 p.

Pashin, J.C., 1994, Flexurally influenced eustatic cycles in the Pottsville Formation (Lower Pennsylvanian), Black Warrior Basin, Alabama, in J.M. Dennison and F.R. Ettensohn, eds., Tectonic and eustatic controls on sedimentary cycles: SEPM Concepts in Sedimentology and Paleontology, v. 4, p. 89-105.Pashin, J.C., 1998, Stratigraphy and structure of coalbed methane reservoirs in the United States: an overview, in R.M. Flores, ed., Coalbed methane: from coal-mine outbursts to a gas resource: International Journal of Coal Geology, v. 35, p. 209-240.Pashin, J.C., 2004, Cyclothems of the Black Warrior Basin, Alabama, U.S.A.: eustatic snapshots of foreland basin tectonism, in J.C. Pashin and R.A. Gastaldo, eds., Sequence stratigraphy, paleoclimate, and tectonics of coal-bearing strata: AAPG Studies in Geology 51, p. 199-217.Pashin, J.C., 2004, Geologic heterogeneity and coalbed methane production—experience from the Black Warrior Basin, in P.D. Warwick, ed., Selected presentations on coal-bed gas in the eastern United States: U.S. Geological Survey Open File Report 2004-1273, p. 61-92. (http://pubs.usgs.gov/of/2004/1273/)Pashin, J.C., 2008, Coal as a petroleum source rock and reservoir rock, in I. Suárez-Ruiz and J.C. Crelling, eds., Applied coal petrology: the role of petrology in coal utilization: New York, Academic Press, p. 227-262.Pashin, J.C., 2009, Implications of variable gas saturation in coalbed methane reservoirs of the Black Warrior Basin, in T. Carr, T. D’Agostino, W. Ambrose, J. Pashin, and N.C. Rosen, eds., Unconventional energy resources: making the unconventional conventional: 29 th Annual GCSSEPM Foundation Bob F. Perkins Research Conference, CD-ROM, p. 329-352.

Pashin, J.C., and M.R. McIntyre, 2003, Temperature-pressure conditions in coalbed methane reservoirs of the Black Warrior basin: implications for carbon sequestration and enhanced coalbed methane recovery: International Journal of Coal Geology, v. 54, p. 167-183.Pashin, J.C., and M.R. McIntyre, 2003, Temperature-pressure conditions in coalbed methane reservoirs of the Black Warrior basin: implications for carbon sequestration and enhanced coalbed methane recovery: International Journal of Coal Geology, v. 54, p. 167-183.Pashin, J.C., and R.E. Carroll, 2002, Influence of coal quality on the carbon sequestration potential of coalbed methane reservoirs in the Black Warrior basin (abstract): AAPG Annual Convention Official Program, v. 11, p. A137.Pashin, J.C., and R.E. Carroll, 2002, Influence of coal quality on the carbon sequestration potential of coalbed methane reservoirs in the Black Warrior basin (abstract): AAPG Annual Convention Official Program, v. 11, p. A137.

Pashin, J.C., J.W. Payton, and G. Jin, 2002, Application of discrete fracture network models to coalbed methane reservoirs in the Black Warrior basin (abstract): AAPG Annual Convention Official Program, v. 11, p. A137.Pashin, J.C., M.R. McIntyre-Redden, S.D. Mann, D.C. Kopaska-Merkel, M. Varonka, and W. Orem, 2014, Relationships between water and gas chemistry in mature coalbed methane reservoirs of the Black Warrior Basin: International Journal of Coal Geology, v. 126, p. 92-105.Pashin, J.C., M.R. McIntyre-Redden, S.D. Mann, D.C. Kopaska-Merkel, M. Varonka, and W. Orem, 2014, Relationships between water and gas chemistry in mature coalbed methane reservoirs of the Black Warrior Basin: International Journal of Coal Geology, v. 126, p. 92-105.

Pashin, J.C., R.H. Groshong, Jr., and R.E. Carroll, 2001, Carbon sequestration potential of coalbed methane reservoirs in the Black Warrior basin: a preliminary look: Tuscaloosa, Alabama, Proceedings, International Coalbed Methane Symposium, Paper 143, p. 51-62.Pashin, J.C., R.H. Groshong, Jr., and R.E. Carroll, 2001, Carbon sequestration potential of coalbed methane reservoirs in the Black Warrior basin: a preliminary look: Tuscaloosa, Alabama, Proceedings, International Coalbed Methane Symposium, Paper 143, p. 51-62.

Pasley, M.A., and J.C. Crelling, 1988, Fluorescent spectral types of selected Colorado bituminous coals: Organic Geochemistry, v. 12, p. 333-343.Pasley, M.A., and J.C. Crelling, 1988, Fluorescent spectral types of selected Colorado bituminous coals: Organic Geochemistry, v. 12, p. 333-343.Pasley, M.A., W.A. Gregory, and G.F. Hart, 1991, Organic matter variations in transgressive and regressive shales: Organic Geochemistry, v. 17, p. 483-509.Passey, S.R., 2014, The habit and origin of siderite spherules in the Eocene coal-bearing Prestfjall Formation, Faroe Islands: International Journal of Coal Geology, v. 122, p. 76-90.Patching, T.C., 1970, The retention and release of gas in coal — a review: Canadian Institute of Mining and Metallurgy, CIM Transactions, v. 63, p. 1302-1308.Patience, R.L., 2003, Where did all the coal gas go?: Organic Geochemistry, v. 34, p. 375-387.Patrick, J.W., 1983, Microscopy of porosity in metallurgical cokes: Journal of Microscopy, v. 132, pt. 3, p. 333-343.

Patrick, J.W., M.J. Reynolds, and F.H. Shaw, 1973, Development of optical anisotropy in vitrains during carbonization: Fuel, v. 52, p. 198-204.Patrick, J.W., M.J. Reynolds, and F.H. Shaw, 1979, Optical anisotropy of carbonized coking- and caking-coal vitrains: Fuel, v. 58, p. 501-509.Patrick, J.W., M.J. Sims, and A.E. Stacey, 1977, Quantitative characterization of the texture of coke: Journal of Microscopy, v. 109, pt. 1, p. 137-143.Patrick, J.W., P.D. Green, K.M. Thomas, and A. Walker, 1989, The influence of pressure on the development of optical anisotropy during carbonization of coal: Fuel, v. 69, p. 149-154.

Patzek, T.W., 2010, Subsurface sequestration of CO2 in the U.S.: Is it money best spent?: Natural Resources Research, v. 19, no. 1, p. 1-9.Patzek, T.W., and G.D. Croft, 2009, Potential for coal-to-liquids conversion in the United States—Fischer–Tropsch synthesis: Natural Resources Research, v. 18, no. 3.Paul, S., and R. Chatterjee, 2011, Determination of in-situ stress direction from cleat orientation mapping for coal bed methane exploration in south-eastern part of Jharia coalfield, India: International Journal of Coal Geology, v. 87, p. 87-96.Paul, S., and R. Chatterjee, 2011, Mapping of cleats and fractures as an indicator of in-situ stress orientation, Jharia coalfield, India: International Journal of Coal Geology, v. 88, p. 113-122.Pavlish, J.H., E.A. Sondreal, M.D. Mann, E.S. Olson, K.C. Galbreath, D.L. Laudal, and S.A. Benson, 2003, A status review of mercury control options for coal-fired power plants: Fuel Processing Technology, v. 82, p. 89-165.Pavlish, J.H., L.L. Hamre, and Y. Zhuang, 2010, Mercury control technologies for coal combustion and gasification systems: Fuel, v. 89, p. 838-847.Pawlewicz, M.J., 1987, Polishing method for dispersed vitrinite and coal slides: TSOP Newsletter, v. 4, no. 1, p. 1,5.

Pashin, J.C., and J.C. Sarnecki, 1990, Coal-bearing strata near Oak Grove and Brookwood coalbed-methane fields, Black Warrior Basin, Alabama: Guidebook for field trip 5, 39th Annual Meeting, Southeastern Section, Geological Society of America, 37 p. http://www.gsa.state.al.us/gsa/pubs/onlinepubs/Guidebooks/GB3-5.pdf

Pashin, J.C., and R.H. Groshong, Jr., 1998, Structural control of coalbed methane production in Alabama, in P.C. Lyons, ed., Special issue: Appalachian coalbed methane: International Journal of Coal Geology, v. 38, p. 89-113.

Pashin, J.C., R.E. Carroll, J.R. Hatch, and M.B. Goldhaber, 1999, Mechanical and thermal control of cleating and shearing in coal: examples from the Alabama coalbed methane fields, USA, in M. Mastalerz, M. Glikson, and S.D. Golding, eds., Coalbed methane: scientific, environmental and economic evaluation: Boston, Kluwer Academic Publishers, p. 305-327.Pashin, J.C., R.E. Carroll, R.H. Groshong, Jr., D.E. Raymond, M. McIntyre, and W.J. Payton, 2002, Geologic screening criteria for sequestration of CO2 in coal: quantifying potential of the Black Warrior coalbed methane fairway, Alabama: U.S. Department of Energy, National Energy Technology Laboratory, Annual Technical Progress Report. http://www.gsa.state.al.us/gsa/CO2PAGE/CO2page.htmPashin, J.C., R.E. Carroll, R.H. Groshong, Jr., D.E. Raymond, M. McIntyre, and W.J. Payton, 2002, Geologic screening criteria for sequestration of CO2 in coal: quantifying potential of the Black Warrior coalbed methane fairway, Alabama: U.S. Department of Energy, National Technology Laboratory, Annual Technical Progress Report. http://www.gsa.state.al.us/gsa/CO2PAGE/CO2page.htmPashin, J.C., R.E. Carroll, R.H. Groshong, Jr., D.E. Raymond, M. McIntyre, and W.J. Payton, 2003, Geologic screening criteria for sequestration of CO2 in coal: quantifying potential of the Black Warrior coalbed methane fairway, Alabama: U.S. Department of Energy, National Energy Technology Laboratory, Annual Technical Progress Report, 209 p. http://www.gsa.state.al.us/gsa/CO2PAGE/CO2page.htm

Pashin, J.C., R.H. Groshong, Jr., and R.E. Carroll, 2001, Enhanced coalbed methane recovery through sequestration of carbon dioxide: potential for a market-based environmental solution in the Black Warrior basin of Alabama: National Energy Technology Laboratory, First National Conference on Carbon Sequestration, 14 p. http://www.netl.doe.gov/publications/proceedings/01/carbon_seq/3a2.pdfPashin, J.C., R.H. Groshong, Jr., and R.E. Carroll, 2001, Enhanced coalbed methane recovery through sequestration of carbon dioxide: potential for a market-based environmental solution in the Black Warrior basin of Alabama: National Energy Technology Laboratory First National Conference on Carbon Sequestration, 14 p. http://www.netl.doe.gov/publications/proceedings/01/carbon_seq/3a2.pdfPashin, J.C., W.E. Ward II, R.B. Winston, R.V. Chandler, D.E. Bolin, K.E. Richter, W.E. Osborne, and J.C. Sarnecki, 1991, Regional analysis of the Black Creek-Cobb coalbed-methane target interval, Black Warrior basin, Alabama: Geological Survey of Alabama Bulletin 145, 127 p. (http://www.gsa.state.al.us/gsa/pubs/onlinepubs/Bulletins/B145.pdf)

Patrick, J.W., 2009, The 7th European conference on coal research and its application (preface): Fuel, v. 88, p. 2327.Patrick, J.W., 2009, The 7th European conference on coal research and its application (preface): Fuel, v. 88, p. 2327.Patrick, J.W., 2009, The 7th European conference on coal research and its application (preface): Fuel, v. 88, p. 2327.Patrick, J.W., and H.C. Wilkinson, 1978, Analysis of metallurgical cokes, in C. Karr, Jr., ed., Analytical methods for coal and coal products, v. 2: New York, Academic Press, p. 339-370.

Pattison, C.I., C.R. Fielding, R.H. McWatters, and L.H. Hamilton, 1996, Nature and origin of fractures in Permian coals from the Bowen basin, Queensland, Australia, in R. Gayer and I. Harris, eds., Coalbed methane and coal geology: London, Geological Society Special Publication 109, p. 133-150.

Pawlewicz, M.J., and C.E. Barker, 1989, Vitrinite reflectance of Tertiary coal across the surface of the northern Powder River basin, Wyoming-Montana: 1989 Montana Geological Society Field Conference, p. 341-351.

Paxton, S.T., 1983, Relationships between Pennsylvanian-age lithic sandstone and mudrock diagenesis and coal rank in the central Appalachians: University Park, The Pennsylvania State University, unpublished PhD dissertation, 503 p.Pearson, D.E., 1991, Probability analysis of blended coking coals: International Journal of Coal Geology, v. 19, p. 109-119.Pearson, D.E., and J. Kwong, 1979, Mineral matter as a measure of oxidation of a caking coal: Fuel, v. 58, p. 63-66.Pearson, D.E., and S. Creaney, 1981, Reflectance of carbonized vitrinites as a measure of oxidation of a coking coal: Fuel, v. 60, p. 273-275.Pearson, J., and D.G. Murchison, 1989, Influence of a sandstone washout on the properties of an underlying coal seam: Fuel, v. 69, p. 251-253.

Pedersen, G.K., L.A. Andersen, E.B. Lundsteen, H.I. Petersen, J.A. Bojesen-Koefoed, and H.P. Nytoft, 2006, Depositional environments, organic maturity and petroleum potential of the Cretaceous coal-bearing Atane Formation at Qullissat, Nuussuaq Basin, West Greenland: Journal of Petroleum Geology, v. 29, p. 3-26.

Pelofsky, A.H., ed., 1979, Coal conversion technology, problems and solutions: Washington, D.C., American Chemical Society, Symposium Series 110, 257 p.Peng, Y., J. Liu, W. Zhu, Z. Pan, and L. Connell, 2014, Benchmark assessment of coal permeability models on the accuracy of permeability prediction: Fuel, v. 132, p. 194-203.Peniguel, G., R. Couderc, and C. Seyve, 1989, Microalgae - their importance in stratigraphy and petroleum exploration: Bulletin Centres Recherches Exploration - Production, Elf Aquitaine, v. 13, p. 455-482.Penner, T.J., J.M. Foght, and K. Budwill, 2010, Microbial diversity of western Canadian subsurface coal beds and methanogenic coal enrichment cultures: International Journal of Coal Geology, v. 82, p. 81-93. (biogenic)Penny, G.S., M.W. Conway, S.W. Almond, R. Himes, and K.E. Nick, 1996, The mechanisms and impact of damage resulting from hydraulic fracturing: Gas Research Institute, Topical Report, GRI-96/0183, variously pagenated.Pentari, D., J. Typou, F. Goodarzi, and A.E. Foscolos, 2006, Comparison of elements of environmental concern in regular and reclaimed soils, near abandoned coal mines Ptolemais-Amynteon, northern Greece: impacts on wheat crops: International Journal of Coal Geology, v. 65, p. 51-58.

Perera, M.S.A., P.G. Ranjith, and S.K. Choi, 2013, Coal cleat permeability for gas movement under triaxial, non-zero lateral strain condition: A theoretical and experimental study: Fuel, v. 109, p. 389-399.Perera, M.S.A., P.G. Ranjith, S.K. Choi, and A. Bouazza, 2013, A parametric study of coal mass and cap rock behaviour and carbon dioxide flow during and after carbon dioxide injection: Fuel, v. 106, p. 129-138.Perera, M.S.A., P.G. Ranjith, S.K. Choi, and D. Airey, 2012, Investigation of temperature effect on permeability of naturally fracture black coal for carbon dioxide movement: An experimental and numerical study: Fuel, v. 94, p. 596-605.Perera, M.S.A.., P.G. Ranjith, D.R. Viete, and S.K. Choi, 2012, Parameters influencing the flow performance of natural cleat systems in deep coal seams experiencing carbon dioxide injection and sequestration: : International Journal of Coal Geology, v. 104, p. 96-106.Permana, A.K., C.R. Ward, Z. Li, and L.W. Gurba, 2013, Distribution and origin of minerals in high-rank coals of the South Walker Creek area, Bowen Basin, Australia: International Journal of Coal Geology, v. 116-117, p. 185-207.Permanyer, A., J.L.R. Gallego, M.A. Caja, and D. Dessort, 2010, Crude oil biodegradation and environmental factors at the Riutort oil shale mine, SE Pyrenees: Journal of Petroleum Geology, v. 33, p. 123-139.Perrotta, A.J., J.P. McCullough, O.A. Larson, and R.J. Gray, 1984, Pressure-temperature microscopy of coal liquefaction: International Journal of Coal Geology, v. 4, p. 235-247.Perry, J.H., G.N. Aul, and J. Cervik, 1978, Methane drainage study in the Sunnyside coalbed, Utah: U.S. Bureau of Mines, Report of Investigations 8323.Perry, J.H., L.J. Prosser, Jr., and S.W. Lambert, 1980, Degasification of the Mary Lee coal bed, Brookwood, Alabama: U.S. Bureau of Mines Report of Investigations 8669, 13 p.Perry, K.F., 2005, Technology key in unconventional gas: American Oil & Gas Reporter, v. 48, no. 5, p. 73-77.Perry, M.B., 2004, Clean coal technology: Boston, Elsevier Academic Press, Encyclopedia of Energy, vol. 1, p. 343-357.Peters, D.C., ed., 1991, Geology in coal resource utilization: Fairfax, VA, Techbooks, 581 p. (available from AAPG)Peters, D.C., ed., 1991, Geology in coal resource utilization: Fairfax, VA, Techbooks, 581 p. (available from AAPG)Peters, K.E., 1986, Guidelines for evaluating petroleum source rock using programmed pyrolysis: AAPG Bulletin, v. 70, p. 318-329.Peters, K.E., and J.M. Moldowan, 1993, The biomarker guide: interpreting molecular fossils in petroleum and ancient sediments: Englewood Cliffs, Prentice-Hall, Inc., 360 p.

Peters, K.E., C.C. Walters, and J.M. Moldowan, 2005, The biomarker guide, second edition: New York, Cambridge University Press, two volumes, 1,155 p.Peters, K.E., C.C. Walters, and J.M. Moldowan, 2005, The biomarker guide, second edition: New York, Cambridge University Press, two volumes, 1,155 p. (p. 89-94)Peters, K.E., C.C. Walters, and J.M. Moldowan, 2010, The biomarker guide volume 1. Biomarkers and isotopes in the environment and human history: Cambridge, Cambridge University Press, 492 p.

Pawlewicz, M.J., 1988, Microlithotype analysis of three coals from the Upper Cretaceous Menefee Formation near Durango, Colorado, in J.E. Fassett, ed., Geology and coal-bed methane resources of the northern San Juan Basin, Colorado and New Mexico: Denver, Rocky Mountain Association of Geologists, p. 81-89.

Pawlewicz, M.J., and J.D. King, 1992, Vitrinite and solid bitumen reflectance: some correlations and applications, in L.B. Magoon, ed., The petroleum system -- status of research and methods, 1992: U.S. Geological Survey Bulletin 2007, p. 58-60.Pawlewicz, M.J., and J.D. King, 1992, Vitrinite and solid bitumen reflectance: some correlations and applications, in L.B. Magoon, ed., The petroleum system — status of research and methods, 1992: U.S. Geological Survey, Bulletin 2007, p. 58-60.

Pearson, M.J., and D. Watkins, 1983, Organofacies and early maturation effects in Upper Jurassic sediments from the Inner Moray Firth basin, North Sea, in J. Brooks, ed., Petroleum geochemistry and exploration of Europe: Boston, Blackwell Scientific Publications, Geological Society Special Publication 12, p. 147-160.

Pedraza, J.E., D. Laverde, C. Vasquez, A. Rincon, and S. Nino, 1995, Simulation and optimization of Columbian coal mixtures in cokemaking, in J.A. Pajares and J.M.D. Tascon, eds., Coal science: New York, Elsevier, Coal science and technology 24, v. 1, p. 1057-1060.

Pepper, A.S., 1991, Estimating the petroleum expulsion behaviour of source rocks: a novel quantitative approach, in W.A. England and A.J. Fleet, eds., Petroleum migration: London, The Geological Society Special Publication 59, p. 9-31.Perch, M., 1981, Solid products of pyrolysis, in M.A. Elliott, ed., Chemistry of coal utilization—second supplementary volume: New York, John Wiley and Sons, p. 919-981.

Peters, K.E., and M.R. Cassa, 1994, Applied source rock geochemistry, in L.B. Magoon and W.G. Dow, eds., The petroleum system -- from source to trap: AAPG Memoir 60, p. 93-120.Peters, K.E., and M.R. Cassa, 1994, Applied source rock geochemistry, in L.B. Magoon and W.G. Dow, eds., The petroleum system—from source to trap: AAPG Memoir 60, p. 93-120.Peters, K.E., and M.R. Cassa, 1994, Applied source rock geochemistry, in L.B. Magoon and W.G. Dow, eds., The petroleum system—from source to trap: AAPG Memoir 60, p. 93-120.

Peters, K.E., J.W. Snedden, A. Sulaeman, J.E. Sarg, and R.J. Enrico, 2000, A new geochemical-sequence stratigraphic model for the Mahakam Delta and Makassar Slope, Kalimantan, Indonesia: AAPG Bulletin, v. 84, p. 12-44.Peters, W. C., 1978, Exploration and Mining Geology: New York, John Wiley & Sons, 696 p.Petersen, H.I., 1993, Petrographic facies analysis of Lower and Middle Jurassic coal seams on the island of Bornholm, Denmark: International Journal of Coal Geology, v. 22, p. 189-216.Petersen, H.I., 1998, Morphology, formation and palaeoenvironmental implications of naturally formed char particles in coals and carbonaceous mudstones: Fuel, v. 77, p. 1177-1183.Petersen, H.I., 1998, Morphology, formation and palaeoenvironmental implications of naturally formed char particles in coals and carbonaceous mudstones: Fuel, v. 77, p. 1177-1183.Petersen, H.I., 2002, A re-consideration of the "oil window" for humic coal and kerogen type III source rocks: Journal of Petroleum Geology, v. 25, p. 407-431.Petersen, H.I., 2002, A re-consideration of the "oil window" for humic coal and kerogen type III source rocks: Journal of Petroleum Geology, v. 25, p. 407-432.Petersen, H.I., 2004, Coal facies studies in Denmark and Greenland: International Journal of Coal Geology, v. 58, p. 53-59.Petersen, H.I., 2006, The petroleum generation potential and effective oil window of humic coals related to coal composition and age: International Journal of Coal Geology, v. 67, p. 221-248.Petersen, H.I., A. Foopatthanakamol, and B. Ratanasthien, 2006, Petroleum potential, thermal maturity and the oil window of oil shales and coals in Cenozoic rift basins, central and northern Thailand: Journal of Petroleum Geology, v. 29, p. 337-360.Petersen, H.I., A. Foopatthanakamol, and B. Ratanasthien, 2006, Petroleum potential, thermal maturity and the oil window of oil shales and coals in Cenozoic rift basins, central and northern Thailand: Journal of Petroleum Geology, v. 29, p. 337-360.Petersen, H.I., and B. Ratanasthien, 2011, Coal facies in a Cenozoic paralic lignite bed, Krabi Basin, southern Thailand: Changing peat-forming conditions related to relative sea-level controlled watertable variations: International Journal of Coal Geology, v. 87, p. 2-12.Petersen, H.I., and H. Vosgerau, 1999, Composition and organic maturity of Middle Jurassic coals, north-east Greenland: evidence for liptinite-induced suppression of huminite reflectance: International Journal of Coal Geology, v. 41, p. 257-274.Petersen, H.I., and H. Vosgerau, 1999, Composition and organic maturity of Middle Jurassic coals, North-East Greenland: evidence for liptinite-induced suppression of huminite reflectance: International Journal of Coal Geology, v. 41, p. 257-274.Petersen, H.I., and H.P. Nytoft, 2006, Oil generation capacity of coals as a function of coal age and aliphatic structure: Organic Geochemistry, v. 37, p. 558-583.Petersen, H.I., and H.P. Nytoft, 2007, Are Carboniferous coals from the Danish North Sea oil-prone?: Geological Survey of Denmark and Greenland, Bulletin 13, p. 13-16.Petersen, H.I., and H.P. Nytoft, 2007, Assessment of the petroleum generation potential of lower Carboniferous coals, North Sea: evidence for inherently gas-prone source rocks: Petroleum Geoscience, v. 13, p. 271-285.Petersen, H.I., and L.H. Nielsen, 1995, Controls on peat accumulation and depositional environments of a coal-bearing coastal plain succession of a pull-apart basin; a petrographic, geochemical and sedimentological study, Lower Jurassic, Denmark: International Journal of Coal Geology, v. 27, p. 99-129.Petersen, H.I., and P. Rosenberg, 1998, Reflectance retardation (suppression) and source rock properties related to hydrogen-enriched vitrinite in Middle Jurassic coals, Danish North Sea: Journal of Petroleum Geology, v. 21, p. 247-263.Petersen, H.I., and P. Rosenberg, 1998, Reflectance retardation (suppression) and source rock properties related to hydrogen-enriched vitrinite in Middle Jurassic coals, Danish North Sea: Journal of Petroleum Geology, v. 21, p. 247-263.Petersen, H.I., and P. Rosenberg, 2000, The relationship between the composition and rank of humic coals and their activation energy distributions for the generation of bulk petroleum: Petroleum Geoscience 6, p. 137-149.Petersen, H.I., and T. Brekke, 2001, Source rock analysis and petroleum geochemistry of the Trym discovery, Norwegian North Sea: a Middle Jurassic coal-sourced petroleum system: Marine and Petroleum Geology, v. 18, p. 889-908.Petersen, H.I., C. Anderson, A.C. Holme, A.D. Carr, and E. Thomsen, 2012, Vitrinite reflectance gradients of deep wells with thick chalk sections and high pressure: Implications for source rock maturation, Danish-Norwegian Central Graben, North Sea: International Journal of Coal Geology, v. 100, p. 65-81.Petersen, H.I., H.P. Nytoft, and L.H. Nielsen, 2004, Characterisation of oil and potential source rocks in the northeastern Song Hong Basin, Vietnam: indications of a lacustrine-coal sourced petroleum system: Organic Geochemistry, v. 35, p. 493-515.Petersen, H.I., J. Andsbjerg, J.A. Bojesen-Koefoed, and H.P. Nytoft, 2000, Coal-generated oil: source rock evaluation and petroleum geochemistry of the Lulita oilfield, Danish North Sea: Journal of Petroleum Geology, v. 23, p. 55-90.Petersen, H.I., J. Andsbjerg, J.A. Bojesen-Koefoed, H.P. Nytoft, and P. Rosenberg, 1998, Petroleum potential and depositional environments of Middle Jurassic coals and non-marine deposits, Danish Central Graben, with special reference to the Søgne Basin: Geological Survey of Denmark, Bulletin 36, 78 p.Petersen, H.I., J.A. Bojesen-Koefoed, and H.P. Nytoft, 2002, Source rock evaluation of Middle Jurassic coals, northeast Greenland, by artificial maturation: aspects of petroleum generation from coal: AAPG Bulletin, v. 86, p. 233-256.Petersen, H.I., J.A. Øverland, T. Solbakk, J.A. Bojesen-Koefoed, and M. Bjerager, 2013, Unusual resinite-rich coals found in northeastern Greenland and along the Norwegian coast: Petrographic and geochemical composition: International Journal of Coal Geology, v. 109-110, p. 58-76.Petersen, H.I., J.A. Øverland, T. Solbakk, J.A. Bojesen-Koefoed, and M. Bjerager, 2013, Unusual resinite-rich coals found in northeastern Greenland and along the Norwegian coast: Petrographic and geochemical composition: International Journal of Coal Geology, v. 109-110, p. 58-76.Petersen, H.I., N. Sherwood, A. Mathiesen, M.B.W. Fyhn, N.T. Dau, N. Russell, J.A. Bojesen-Koefoed, and L.H. Nielsen, 2009, Application of integrated vitrinite reflectance and FAMM analyses for thermal maturity assessment of the northeastern Malay Basin, offshore Vietnam: Implications for petroleum prospectivity evaluation: marine and Petroleum Geology, v. 26, p. 319-332.Petersen, H.I., N. Sherwood, A. Mathiesen, M.B.W. Fyhn, N.T. Dau, N. Russell, J.A. Bojesen-Koefoed, and L.H. Nielsen, 2009, Application of integrated vitrinite reflectance and FAMM analyses for thermal maturity assessment of the northeastern Malay Basin, offshore Vietnam: Implications for petroleum prospectivity evaluation: marine and Petroleum Geology, v. 26, p. 319-332.Petersen, H.I., N.H. Schovsbo, and A.T. Nielsen, 2013, Reflectance measurements of zooclasts and solid bitumen in Lower Paleozoic shales southern Scandinavia: Correlation to vitrinite reflectance: International Journal of Coal Geology, v. 114, p. 1-18.Petersen, H.I., N.H. Schovsbo, and A.T. Nielsen, 2013, Reflectance measurements of zooclasts and solid bitumen in Lower Paleozoic shales southern Scandinavia: Correlation to vitrinite reflectance: International Journal of Coal Geology, v. 114, p. 1-18.Petersen, H.I., P. Rosenberg, and H.P. Nytoft, 2008, Oxygen groups in coals and alginate-rich kerogen revisited: International Journal of Coal Geology, v. 74, p. 93-113.Petersen, H.I., P. Rosenberg, and J. Andsbjerg, 1996, Organic geochemistry in relation to the depositional environments of Middle Jurassic coal seams, Danish central graben, and implications for hydrocarbon generative potential: AAPG Bulletin, v. 80, p. 47-62.Petersen, H.I., P. Rosenberg, and J. Andsbjerg, 1996, Organic geochemistry in relation to the depositional environments of Middle Jurassic coal seams, Danish central graben, and implications for hydrocarbon generative potential: AAPG Bulletin, v. 80, p. 47-62.Petersen, H.I., S. Lindström, H.P. Nytoft, and P. Rosenberg, 2009, Composition, peat-forming vegetation and kerogen paraffinicity of Cenozoic coals: Relationship to variations in the petroleum generation potential (Hydrogen Index): International Journal of Coal Geology, v. 78, p. 119-134.Petersen, H.I., S. Lindström, J. Therkelsen, and G.K. Pedersen, 2013, Deposition, floral composition and sequence stratigraphy of uppermost Triassic (Rhaetian) coastal coals, southern Sweden: International Journal of Coal Geology, v. 116-117, p. 117-134.Petersen, H.I.., H.P. Nytoft, B. Ratanasthien, and A. Foopatthanakamol, 2007, Oils from Cenozoic rift-basins in central and northern Thailand: source and thermal maturity: Journal of Petroleum Geology, v. 30, p. 59-78.Petersen, K.M., 1991, Coalbed gas development in the western United States—an update, in S.D. Schwochow, D.K. Murray, and M.F. Fahy, eds., Coalbed methane of western North America: Denver, CO, Rocky Mountain Association of Geologists Guidebook, p. 297-312.Peterson, E.B., and N.M. Peterson, 2002, Selected annotated references on water handling, environmental, and land-use aspects of coalbed methane development: Victoria, B.C., B.C. Ministry of Energy and Mines, 109 p. (http://www.em.gov.bc.ca/dl/Oilgas/pub/CBM_Biblio.pdf)

Petroleum Frontiers, 1986, Coalbed methane - an old hazard becomes a new resource: Petroleum Frontiers, v. 3, no. 4, 65 p.Petroleum Frontiers, 2001, Emerging coalbed methane plays of North America: Petroleum Frontiers, v. 18, no. 3 60 p.

Petsch, S.T., R.A. Berner, and T.I. Eglinton, 2000, A field study of the chemical weathering of ancient sedimentary organic matter: Organic Geochemistry, v. 31, p. 475-487.

Petzet, A., 2003, Coal gas down under: Oil & Gas Journal, v. 101.8, p. 17.Petzet, A., 2005, Resource plays, CBM to fuel drilling upturns in US, Canada: Oil & Gas Journal, v. 103.3, p. 32-34.Petzet, A., 2007, The rise of coalbed methane: Oil & Gas Journal, v. 105.47, p. 19.Petzet, A., 2007, Water issues overshadow Powder River coal gas play: Oil & Gas Journal, v. 105.4, p. 30-36.Peucker-Ehrenbrink, B., and R.E. Hannigan, 2000, Effects of black shale weathering on the mobility of rhenium and platimum group elements: Geology, v. 28, p. 475-478.Pflughoeft-Hassett, D.F., 2000, Practical working definition for materials from conversion of coal for power production: Energeia, v. 11, no. 4, p. 1-3.Philippi, G.T., 1974, The influence of marine and terrestrial source material on the composition of petroleum: Geochimica et Cosmochimica Acta, v. 38, p. 947-966.Phillips, S., and R.M. Bustin, 1996, Sedimentology of the Changuinola peat deposit: organic and clastic sedimentary deposit: organic and clastic sedimentary response to punctuated coastal subsidence: Geological Society of America Bulletin, v. 108, p. 794-814.Phillips, S., R.M. Bustin, and L.E. Lowe, 1994, Earthquake-induced flooding of a tropical coastal peat swamp: a modern analogue for high-sulfur coals?: Geology, v. 22, p. 929-932.Phillips, T.L., 1980, Stratigraphic and geographic occurrences of permineralized coal-swamp plants - Upper Carboniferous of North America and Europe, in D.L. Dilcher and T.N. Taylor, eds., Biostratigraphy of fossil plants, successional and paleoecological analyses: Stroudsburg, Pennsylvania, Dowden, Hutchinson & Ross, Inc., p. 25-92.Phillips, T.L., A.B. Kunz, and D.J. Mickish, 1977, Paleobotany of permineralized peat (coal balls) from the Herrin (no. 6) coal member of the Illinois basin: Geological Society of America Microform Publication, v. 7, p. 18-49.

Phillips, T.L., and C.B. Cecil, eds., 1985, Paleoclimatic controls on coal resources of the Pennsylvanian System of North America: International Journal of Coal Geology, v. 5, 230 p.Phillips, T.L., and R.A. Peppers, 1984, Changing patterns of Pennsylvanian coal-swamp vegetation and implications of climate control on occurrence: International Journal of Coal Geology, v. 3, p. 205-255.Phillips, T.L., and W.A. Dimichele, 1990, From plants to coal: peat taphonomy of Upper Carboniferous coals: International Journal of Coal Geology, v. 16, p. 151-156.Phillips, T.L., M.J. Avcin, and D.J. Berggren, 1976, Fossil peat from the Illinois basin - a guide to the study of coal balls of Pennsylvanian age: Illinois State Geological Survey Educational Series 11, 39 p.Phillips, T.L., R.A. Peppers, and W.A. Dimichele, 1985, Stratigraphic and interregional changes in Pennsylvanian coal-swamp vegetation: environmental inferences: International Journal of Coal Geology, v. 5, p. 43-109.Phillips, T.L., R.A. Peppers, M.J. Avcin, and P.F. Laughnan, 1974, Fossil plants and coal: patterns of change in Pennsylvanian coal swamps of the Illinois Basin: Science, v. 184, p. 1367-1369.

Phipps, D., and G. Playford, 1984, Laboratory techniques for the extraction of palynomorphs from sediments: Pap. Dep. Geol. Univ. Queensland, v. 11, p. 1-23.

Picciano, L., 1994, Coalbed methane research: selected bibliography: Gas Research Institute, Topical Report, GRI-94/0473, 49 p.Pickard, R.J., and J.M. Selkirk, 1997, An improved hand core sampler for peat: AASP, Palynology, v. 21, p. 209-211.

Pickett, A., 2007, Mid-Continent operators finding new methods to exploit old plays: American Oil & Gas Reporter, v. 50, no. 8, p. 122-129.Pickett, A., 2009, Expanding list of projects illustrates CO2 EOR’s merits in revitalizing mature fields: American Oil & Gas Reporter, v. 52, no. 11, p. 60-69.Pickhardt, W., 1989, Trace elements in minerals of German bituminous coals: International Journal of Coal Geology, v. 14, p. 137-153.Piedad-Sánchez, N., A. Izart, L. Martínez, I. Suárez-Ruiz, M. Elie, and C. Menetrier, 2004, Paleothermicity in the central Asturian coal basin, north Spain: International Journal of Coal Geology, v. 58, p. 205-229.

Petsch, S.T., K.J. Edwards, and T.I. Eglinton, 2003, Abundance, distribution and δ13C analysis of microbial phospholipids-derived fatty acids in a black shale weathering profile: Organic Geochemistry, v. 34, p. 731-743.

Petsch, S.T., R.J. Smernik, T.I. Eglinton, and J.M. Oades, 2001, A solid state 13C-NMR study of kerogen degradation during black shale weathering: Geochimica et Cosmochimica Acta, v. 65, p. 1867-1882.

Phillips, T.L., and A.T. Cross, 1991, Paleobotany and paleoecology of coal, in H.J. Gluskoter, D.D. Rice, and R.B. Taylor, eds., Economic geology, U.S.: Geological Society of America, The geology of North America, v. P-2, p. 483-502.Phillips, T.L., and A.T. Cross, 1995, Early and mid-twentieth century coal-ball studies in North America, in P.C. Lyons, E.D. Morey, and R.H. Wagner, eds., Historical perspective of early twentieth century Carboniferous paleobotany in North America: Geological Society of America, Memoir 185, p. 315-339.

Philp, R.P., 1994, Geochemical characteristics of oils derived predominantly from terrigenous source materials, in A.C. Scott and A.J. Fleet, eds., Coal and coal-bearing strata as oil-prone source rocks?: London, The Geological Society Special Publication 77, p. 71-91.Philp, R.P., and A. Galvez-Sinibaldi, 1991, Characterization of organic matter by various pyrolysis techniques, in R.K. Merrill, ed., Source and migration processes and evaluation techniques: AAPG Treatise of Petroleum Geology, Handbook of Petroleum Geology, p. 107-112.Philp, R.P., and J.D. Saxby, 1980, Organic geochemistry of coal macerals from the Sydney Basin (Australia), in A.G. Douglas and J.R. Maxwell, eds., Advances in Organic Geochemistry 1979: New York, Pergamon Press, Physics and Chemistry of the Earth, v. 12, p. 639-651.

Phong-anant, D., J.W. Baker, and M. Salehi, 1989, Burnout characteristics of coal macerals, in C.G. Thomas and M.G. Strachan, eds., Proceedings of the macerals ’89 symposium: North Ryde, NSW, CSIRO, p. 5-1 to 5-19.

Pickel, W., and G.K.E. Gotz, 1991, Investigations on the petroleum generation potential of bituminous coals from the Saar region, in P.K. Mukhopadhyay, M.G. Fowler, and W.G. Dow, eds., Selected papers from the symposium on coal and terrestrial organic matter as a source rock for petroleum: Organic Geochemistry, v. 17, p. 695-704.Pickel, W., M. Wolf, and H.W. Hagemann, 1993, Petrographical and geochemical investigations on coals of different liptinite content: 12 th International Congress of Stratigraphy and Geology of the Carboniferous and Permian, Comptes Rendus, v. 1, p. 253-266.Pickel, W., R. Wilkins, C. Buckingham, M. Faiz, J. Kurusingal, N. Russell, and N. Sherwood, 2001, Laser microscopy–FAMM: ICCP White Paper, 10 p. (rate of oxidation is related to rank; significant reduction in fluorescence intensity in one or two days) http://www.iccop.org/uploads/media/2._Pickel_et_al._-_FAMM_02.pdf Pickel, W., R. Wilkins, C. Buckingham, M. Faiz, J. Kurusingal, N. Russell, and N. Sherwood, 2001, Laser microscopy–FAMM: ICCP White Paper, 10 p. http://www.iccop.org/uploads/media/2._Pickel_et_al._-_FAMM_02.pdf

Pierce, B., 1993, Coalbed methane in the Forest City basin: U.S. Geological Survey, Fact Sheet. http://energy.usgs.gov/factsheets/Forest/forest.htmlPierce, B.S., and K.O. Dennen, 2009, The National Coal Resource Assessment overview: U.S. Geological Survey Professional Paper 1625-F, 402 p. http://pubs.usgs.gov/pp/1625f/

Pierce, B.S., and R.W. Stanton, 1993, Influence of coal bed facies development on the washability of the Upper Freeport coal bed, Pennsylvania: Journal of Coal Quality, v. 12, p. 18-23.Pierce, B.S., R.W. Stanton, and C.F. Eble, 1991, Facies development in the Lower Freeport coal bed, west-central Pennsylvania, U.S.A.: International Journal of Coal Geology, v. 18, p. 17-43.Pierce, B.S., R.W. Stanton, and C.F. Eble, 1993, Comparison of the petrography, palynology and paleobotany of the Stockton coal bed, West Virginia and implications for paleoenvironmental interpretations: Organic Geochemistry, v. 20, p. 149-166.Pierron, E.D., O.W. Rees, and G.L. Clark, 1959, Plastic properties of coal: Illinois State Geological Survey Circular 269, 36 p.

Pilawa, B., A.B. Wieckowski, and B. Trzebicka, 1990, Two component structure of the EPR spectra of coal and its macerals: Erdol und Kohle-Erdgas-Petrochemie, v. 43, p. 187-189.Pilawa, B., A.B. Wieckowski, M. Lewandowski, and Nassalski, 1998, Electron paramagnetic resonance studies of coal macerals—influence of microwave frequency and thermal decomposition: Erdol Erdgas Kohle, v. 114, p. 37-40.Pilawa, B., B. Trzebicka, A.B. Wieckowski, B. Hana, J. Komorek, and S. Pusz, 1991, EPR spectra of exinite, vitrinite and inertinite. Influence of microwave saturation and sample evacuation: Erdol und Kohle-Erdgas-Petrochemie, v. 44, p. 421-425.Pilawa, B., B. Trzebicka, and A.B. Wieckowski, 1992, Coal and its macerals. Multi-component structure of the EPR spectra: Erdol und Kohle-Erdgas-Petrochemie, v. 45, p. 308-312.Pilawa, B., S. Pusz, M. Krzesińska, A. Koszorek, and B. Kwiecińska, 2009, Application of electron paramagnetic resonance spectroscopy to examination of carbonized coal blends: International Journal of Coal Geology, v. 77, p. 372-376.

Pillalamarry, M., S. Harpalani, and S. Liu, 2011, Gas diffusion behavior of coal and its impact on production from coalbed methane reservoirs: International Journal of Coal Geology, v. 86, p. 342-348.Pinetown, K.L., C.R. Ward, and W.A. van der Westhuizen, 2007, Quantitative evaluation of minerals in coal deposits in the Witbank and Highveld coalfields, and the potential impact on acid mine drainage: International Journal of Coal Geology, v. 70, p. 166-183.Pinsker, L.M., 2002, Coalbed methane: the future of U.S. natural gas?: Geotimes, v. 47, no. 11, p. 34-35.Pires, M., and X. Querol, 2004, Characterization of Candiota (South Brazil) coal and combustion by-product: International Journal of Coal Geology, v. 60, p. 57-72.Pironon, J., and B. Pradier, 1992, Ultraviolet-fluorescence alteration of hydrocarbon fluid inclusions: Organic Geochemistry, v. 18, p. 501-509.Pis, J.J., T.A. Centeno, M. Mahamud, A.B. Fuertes, J.B. Parva, J.A. Pajares, and R.C. Bansal, 1996, Preparation of active carbons from coal, part 1. Oxidation of coal: Fuel Processing Technology, v. 47, p. 119-138.Pisupati, S.V., A.W. Scaroni, and P.G. Hatcher, 1993, Devolatilization behaviour of naturally weathered and laboratory oxidized bituminous coals: Fuel, v. 72, p. 165-173.Pisupati, S.V., and A.W. Scaroni, 1993, Natural weathering and laboratory oxidation of bituminous coals: organic and inorganic structural changes: Fuel, v. 72, p. 531-542.Pitman, J.K., and others, 1989, Thickness, oil-yield, and kriged resource estimates for the Eocene Green River Formation, Piceance Creek Basin, Colorado: U.S. Geological Survey Oil and Gas Investigations Chart OC-132,Pitman, J.K., J.C. Pashin, J.R. Hatch, and M.B. Goldhaber, 2003, Origin of minerals in joint and cleat systems of the Pottsville Formation, Black Warrior basin, Alabama: implications for coalbed methane generation and production: AAPG Bulletin, v. 87, p. 713-731.Pitt, G.J., and K.M. Dawson, 1979, Some considerations involved in the automation of reflectance measurements on coal: Journal of Microscopy, v. 116, pt. 3, p. 321-328.

Plumlee, M.H., J.-F. Debroux, D. Taffler, J.W. Graydon, X. Mayer, K.G. Dahm, N.T. Hancock, K.L. Guerra, P. Xu, J.E. Drewes, and T.Y. Cath, 2014, Coalbed methane produced water screening tool for treatment technology and beneficial use: Journal of Unconventional Oil and Gas Resources, v. 5, p. 22-34.Poças Ribeiro, N., J.G. Mendonça Filho, L.V. Duarte, R.L. Silva, J.O. Mendonça, and T.F. Silva, 2013, Palynofacies and organic geochemistry of the Sinemurian carbonate deposits in the western Lusitanian Basin (Portugal): Coimbra and Água de Madeiros formations: International Journal of Coal Geology, v. 111, p. 37-52.Pocknall, D.T., and R.M. Flores, 1987, Coal palynology and sedimentology in the Tongue River member, Fort Union Formation, Powder River Basin, Wyoming: Palaios, v. 2, p. 133-145.

Pocock, S.A.J., G. Vasanthy, and B.S. Venkatachala, 1987, Introduction to the study of particulate organic materials and ecological perspectives: Journal of Palynology, v. 23-24, p. 167-188.Pohlmann, J.G., E. Osorio, A.C.F. Vilela, and A.G. Borrego, 2010, Reactivity to CO2 of chars prepared in O2/N2 and O2/CO2 mixtures for pulverized coal injection (PCI) in blast furnace in relation to char petrographic characteristics: International Journal of Coal Geology, v. 84, p. 293-300.Poinar, G., Jr., J.B. Lambert, and Y. Wu, 2004, NMR analysis of amber in the Zubair Formation, Khafji oilfield (Saudi Arabia—Kuwait): coal as an oil source rock?: Journal of Petroleum Geology, v. 27, p. 207-209.Pollack, H.N., and K.R. Cercone, 1994, Anomalous thermal maturities caused by carbonaceous sediments: Basin Research, v. 6, p. 47-51.Pollard, J.E., 1988, Trace fossils in coal-bearing sequences: Journal of the Geological Society, London, v. 145, p. 339-350.Pone, J.D.N., K.A.A. Hein, G.B. Stracher, H.J. Annegarn, R.B. Finkelman, D.R. Blake, J.K. McCormack, and P. Schroeder, 2007, The spontaneous combustion of coal and its by-products in the Witbank and Sasolburg coalfields of South Africa: International Journal of Coal Geology, v. 72, p. 124-140.Pone, J.D.N., M. Hile, P.M. Halleck, and J.P. Mathews, 2009, Three-dimensional carbon dioxide-induced strain distribution within a confined bituminous coal: International Journal of Coal Geology, v. 77, p. 103-108.Pone, J.D.N., P.M. Halleck, and J.P. Mathews, 2010, 3D characterization of coal strains induced by compression, carbon dioxide sorption, and desorption at in-situ stress conditions: International Journal of Coal Geology, v. 82, p. 262-268.Pone, J.D.N., P.M. Halleck, and J.P. Mathews, 2010, 3D characterization of coal strains induced by compression, carbon dioxide sorption, and desorption at in-situ stress conditions: International Journal of Coal Geology, v. 82, p. 262-268.Pontolillo, J., and R.W. Stanton, 1994, Coal petrographic laboratory procedures and safety manual II: U.S. Geological Survey Open-File Report 94-631, 69 p.Pope, J.M., 2005, Same day downhole critical gas content without the core (abstract): 2005 AAPG Mid-Continent Section Meeting, Final Announcement and Meeting Program, p. 25.Pope, J.M., 2006, Get accurate, CBM reservoir data: Hart’s E&P, v. 79, no. 9, p. 127-128.Pope, J.M., 2006, New technology supports increased E&P success in coalbed natural gas: GasTIPS, v. 12, no. 3, p. 6-8.

Pilarczyk, E., P. Leonhardt, and W. Wanzl, 1995, Characterization of coals with respect to their self-ignition tendency, in J.A. Pajares and J.M.D. Tascon, eds., Coal science: New York, Elsevier, Coal Science and Technology 24, v. 1, p. 497-500.

Pilcher, R.C., R.C. Collings, and J.S. Marshall, 2000, An overview of emerging practices and models used in coal mine methane resource estimation and reserve evaluation: Second International Methane Mitigation Conference, Novosibirsk, Russia, June 2000, 7 p. (available at Raven Ridge web site: www.ravenridge.com)Pilcher, R.C., R.C. Collings, and J.S. Marshall, 2000, An overview of emerging practices and models used in coal mine methane resource estimation and reserve evaluation: Second International Methane Mitigation Conference, Novosibirsk, Russia, June 2000, 7 p. (available at Raven Ridge web site: www.ravenridge.com)

Plaizier, R.R., and V.J. Hucka, 1991, In situ determination of desorbable methane content by use of three decay functions, in S.D. Schwochow, D.K. Murray, and M.F. Fahy, eds., Coalbed methane of western North America: Denver, CO, Rocky Mountain Association of Geologists Guidebook, p. 77-86.

Pocock, S.A.J., 1982, Identification and recording of particulate sedimentary organic matter, in F.L. Staplin and others, How to assess maturation and paleotemperatures: SEPM Short Course Notes 7, p. 13-131.

Pope, J.M., 2009, Best practices for multi-zone coalbed methane completions: 2009 International Coalbed & Shale Gas Symposium, Tuscaloosa, AL, Paper 0933.

Popova, O.H., M.J. Small, S.T. McCoy, A.C. Thomas, B. Karimi, A. Goodman, and K.M. Carter, 2012, Comparative analysis of carbon dioxide storage resource assessment methodologies: Environmental Geosciences Journal, v. 19, no. 3.Popp, J.T., and C.M. McCulloch, 1976, Geological factors affecting methane in the Beckley coalbed: U.S. Bureau of Mines Report of Investigations 8137, 35 p.Popp, J.T., D.D. Coleman, and R.A. Deogh, 1979, Investigations of the gas content of coal seams in the vicinity of Charleston, Illinois: Illinois Institute of Natural Resources, Document 79-38.Porter, D., and J. Schmitz, 1995, Utility coal procurement: London, IEA Coal Research, Perspectives Series, IEAPER/20, 31 p.Porter, H.C., and F.K. Ovitz, 1910, The volatile matter of coal: U.S. Bureau of Mines Bulletin 1, 56 p.Potgieter, J.H., 2003, Fly ash research at Technikon Pretoria, South Africa: Energeia, v. 14, no. 1, p. 1-3.Potter, J., 1999, A genetic approach to the characterization of "microbitumens"; implications for thermal maturity determinations (abstract): TSOP Abstracts and Program, v. 16, p. 11-13.Potter, J., A.P. Beaton, W.J. McDougall, E.M.V. Nambudiri, and L.W. Vigrass, 1991, Depositional environments of the Hart coal zone (Paleocene), Willow Bunch coalfield, southern Saskatchewan, Canada from petrographic, palynological, paleobotanical, mineral and trace element studies: International Journal of Coal Geology, v. 19, p. 253-281.Potter, J., B.C. Richards, and A.R. Cameron, 1993, The petrology and origin of coals from the lower Carboniferous Mattson Formation, southwestern District of Mackenzie, Canada: International Journal of Coal Geology, v. 24, p. 113-140.Potter, J., B.C. Richards, and A.R. Cameron, 1993, The petrology and origin of coals from the lower Carboniferous Mattson Formation, southwestern district of Mackenzie, Canada: International Journal of Coal Geology, v. 24, p. 113-140. (origin of micrinite and macrinite)Potter, J., B.C. Richards, and F. Goodarzi, 1993, The organic petrology and thermal maturity of lower Carboniferous and Upper Devonian source rocks in the Liard basin, at Jackfish Gap-Yohin Ridge and North Beaver River, northern Canada: implications for hydrocarbon exploration: Energy Sources, v. 15, p. 289-314.Potter, J., L.D. Stasiuk, and A.R. Cameron, 1998, A petrographic atlas of Canadian coal macerals and dispersed organic matter: Canadian Society for Coal Science and Organic Petrology, 105 p.

Powell, T.G., 1978, An assessment of the hydrocarbon source rock potential of the Canadian Arctic Islands: Geological Survey of Canada Paper 78-12.Powell, T.G., 1984, Developments in concepts of hydrocarbon generation from terrestrial organic matter: Proceedings of the Beijing Petroleum Symposium, p. 1-36.Powell, T.G., 1986, Petroleum geochemistry and depositional setting of lacustrine source rocks: Marine and Petroleum Geology, v. 3, p. 200-219.

Powell, T.G., and C.J. Boreham, 1991, Petroleum generation and source rock assessment in terrigenous sequences: an update: APEA Journal, v. 31, part 1, p. 297-311.Powell, T.G., and C.J. Boreham, 1991, Petroleum generation and source rock assessment in terrigenous sequences: an update: APEA Journal, v. 31, part 1, p. 297-311.

Powell, T.G., and D.M. McKirdy, 1972, The geochemical characterisation of Australian crude oils: APEA Journal, v. 12, p. 125-131.Powell, T.G., C.J. Boreham, M. Smyth, N. Russell, and A.C. Cook, 1991, Petroleum source rock assessment in non-marine sequences: pyrolysis and petrographic analysis of Australian coals and carbonaceous shales: Organic Geochemistry, v. 17, p. 375-394.Powell, T.G., C.J. Moreham, D.M. McKirdy, B.H. Michaelsen, and R.E. Summons, 1989, Petroleum geochemistry of the Murta member, Mooga Formation, and associated oils, Eromanga basin: APEA Journal, v. 29, part 1, p. 114-129.Powell, T.G., S. Creaney, and L.R. Snowdon, 1982, Limitations of use of organic petrographic techniques for identification of petroleum source rocks: AAPG Bulletin, v. 66, p. 430-435.Prachiti, P.K., C. Manikyamba, P.K. Singh, V. Balaram, G. Lakshminarayana, K. Raju, M.P. Singh, M.S. Kalpana, and M. Arora, 2011, Geochemical systematic and precious metal content of the sedimentary horizons of Lower Gondwanas from the Sattupalli coal field, Godavari Valley, India: International Journal of Coal Geology, v. 88, p. 83-100.Pradier, B., C. Largeau, S. Derenne, L. Martinez, P. Bertrand, and Y. Pouet, 1990, Chemical basis of fluorescence alteration of crude oils and kerogens — I. Microfluorimetry of an oil and its isolated fractions; relationships with chemical structure: Organic Geochemistry, v. 16, p. 451-460.Pradier, B., G. Nicolas, and J. Gerard, 1994, The analysis of the depositional environments of coal, a correlation tool applied to the Brent Group in the North Sea: Bulletin des Centres de Recherches Exploration-Production elf aquitaine, v. 18, p. 121-133.Pradier, B., P. Bertrand, L. Martinez, and F. Laggoun-Defarge, 1991, Fluorescence of organic matter and thermal maturity assessment: Organic Geochemistry, v. 17, p. 511-524.Pradier, B., P. Bertrand, L. Martinez, and F. Laggoun-Defarge, 1991, Fluorescence of organic matter and thermal maturity assessment: Organic Geochemistry, v. 17, p. 511-524.Pradier, B., P. Bertrand, L. Martinez, F. Laggoun, and J.L. Pittion, 1988, Microfluorimetry applied to organic diagenesis study: Organic Geochemistry, v. 13, p. 1163-1167.Pradier, B., P. Landais, A. Rochdi, and A. Davis, 1992, Chemical basis of fluorescence alteration of crude oils and kerogens — II. Fluorescence and infrared micro-spectrometric analysis of vitrinite and liptinite: Organic Geochemistry, v. 18, p. 241-248.Pradier, B., P. Landais, A. Rochdi, and A. Davis, 1992, Chemical basis of fluorescence alteration of crude oils and kerogens—II. Fluorescence and infrared micro-spectrometric analysis of vitrinite and liptinite: Organic Geochemistry, v. 18, p. 241-248.Prado, J.G., 1977, Optical properties of oxidized vitrinite and exinite: Journal of Microscopy, v. 109, p. 85-92.Prahl, F.G., G.J. De Lange, S. Scholten, and G.L. Cowie, 1997, A case of post-depositional aerobic degradation of terrestrial organic matter in turbidite deposits from the Madeira Abyssal Plain: Organic Geochemistry, v. 27, p. 141-152.

Prakash, A., T. Singh, and S.C. Srivastava, 1988, Occurrence of faunal coal balls in Gondwana sediments (Permian) of Arunachal Himalaya, India: International Journal of Coal Geology, v. 9, p. 305-314.Prased, A.S., 1988, Combustion of pulverized coal blends: Norman, University of Oklahoma, unpublished thesis.

Pratt, K.C., 1993, The use of composite and mosaic imaging of polished surfaces to enhance petrographic analysis of coal by image analysis: Organic Geochemistry, v. 20, p. 759-768.

Pope, J.M., D. Buttry, R. Lamarre, B. Noecker, S. MacDonald, B. LaReau, P. Malone, N. Van Lieu, D. Petroski, M. Accurso, D. Harak, R. Kutz, S. Luker, and R. Martin, 2005, Downhole geochemical analysis of gas content and critical desorption pressure for carbonaceous reservoirs, in P. Lufholm and D. Cox, eds., 2005 WTGS Fall Symposium: West Texas Geological Society, Publication No. 05-115, p. 115-122.

Poulton, T.P., 1989, Fossils: thermal maturation indicators, northwestern mainland Canada, in Current research Part G: Geological Survey of Canada Paper 89-1G, p. 23-24.

Powell, T.G., 1988, Developments in concepts of hydrocarbon generation from terrestrial organic matter, in H.C. Wagner, L.C. Wagner, F.F.H. Wang, and F.L. Wong, eds., Petroleum resources of China and related subjects: Houston, Circum-Pacific Council for Energy and Mineral Resources, Earth Science Series, v. 10, p. 807-824.

Powell, T.G., and C.J. Boreham, 1994, Terrestrially sourced oils: where do they exist and what are our limits of knowledge? - a geochemical perspective, in A.C. Scott and A.J. Fleet, eds., Coal and coal-bearing strata as oil-prone source rocks?: London, The Geological Society Special Publication 77, p. 11-29.

Prakash, A., and A.R. Berthelote, 2007, Subsurface coal-mine fires: laboratory simulation, numerical modeling, and depth estimation, in G.B. Stracher, ed., Geology of coal fires: case studies from around the world: GSA Reviews in Engineering Geology 18, p. 211-218.

Pratt, K.C., 1989, The use of automated image analysis to determine conventional coal petrographic parameters -- an example from southeastern British Columbia, in Contributions to Canadian coal geoscience: Geological Survey of Canada Paper 89-8, p. 137-145.

Pratt, S.E., 2013, Missing charcoal flows out to sea: Earth, v. 58, no. 7, p. 17.

Presley, J., 2013, New life for Oklahoma’s North Burbank field, CO2 EOR opens new chapter for an historic field: Hart Energy Publishing, E&P, v. 86, no. 10, p. 92, 95-96.

Price, F.T., and D.J. Casagrande, 1991, Sulfur distribution and isotopic composition in peats from the Okefenokee Swamp, Georgia and the Everglades, Florida: International Journal of Coal Geology, v. 17, p. 1-20.Price, F.T., and D.J. Casagrande, 1991, Sulfur distribution and isotopic composition in peats from the Okefenokee Swamp, Georgia and the Everglades, Florida: International Journal of Coal Geology, v. 17, p. 1-20.Price, L.C., 1989, Hydrocarbon generation and migration from Type III Kerogen as related to the oil window: U.S. Geological Survey, Open-File Report 89-194, 41 p.Price, L.C., and C.E. Barker, 1985, Suppression of vitrinite reflectance in amorphous rich kerogen - a major unrecognized problem: Journal of Petroleum Geology, v. 8, p. 59-84.Price, L.C., and C.E. Barker, 1985, Suppression of vitrinite reflectance in amorphous rich kerogen -- a major unrecognized problem: Journal of Petroleum Geology, v. 8, p. 59-84.Price, L.C., and L.M. Wenger, 1992, The influence of pressure on petroleum generation and maturation as suggested by aqueous pyrolysis: Organic Geochemistry, v. 19, p. 141-159.Price, L.C., T. Daws, and M. Pawlewicz, 1986, Organic metamorphism in the Lower Mississippian-Upper Devonian Bakken Shales, part 1: Rock-Eval pyrolysis and vitrinite reflectance: Journal of Petroleum Geology, v. 9, p. 125-162.Price, P.H., and J.W. Headlee, 1943, Natural coal gas in West Virginia: AAPG Bulletin, v. 27, p. 529-537.Priestman, A., 2009, Gas supply, coalbed methane matures: Oil and Gas Investor, v. 29, no. 6, p. 53-54.

Pross, J., T. Pletsch, D.J. Shillington, B. Ligouis, F. Schellenberg, and J. Kus, 2007, Thermal alteration of terrestrial palynomorphs in mid-Cretaceous organic-rich mudstones intruded by an igneous sill (Newfoundland margin, ODP Hole 1276A): International Journal of Coal Geology, v. 70, p. 277-291.Puri, R., and D. Yee, 1990, Enhanced coalbed methane recovery: Soc. Petroleum Engineers Paper SPE 20732.Puri, R., and J.P. Seidle, 1992, Measurement of stress-dependent permeability in coal and its influence on coalbed methane production: In Situ, v. 16, p. 183-202.

Purushothama, S., and W.G. Lloyd, 1994, Organic coproducts of coal combustion: Journal of Coal Quality, v. 13, p. 77-81.Pusz, S., and R. Buszko, 2012, Reflectance parameters of cokes in relation to their reactivity index (CRI) and the strength after reaction (CSR), from coals of the Upper Silesian coal basin, Poland: International Journal of Coal Geology, v. 90-91, p. 43-49.Pusz, S., B. Kwiecińska, A. Koszorek, M. Krzesińska, and B. Pilawa, 2009, Relationships between the optical reflectance of coal blends and the microscopic characteristics of their cokes: International Journal of Coal Geology, v. 77, p. 356-362.Pusz, S., B.K. Kwiecińska, and S. Duber, 2003, Textural transformation of thermally treated anthracites: International Journal of Coal Geology, v. 54, p. 115-123.Pusz, S., D. Alvarez, I. Camean, V. du Cann, S. Duber, A. Gómez-Borrego, W. Kalkreuth, J. Komorek, J. Kus, B. Kwiecińska, M. Marques, M. Misz, R. Morga, S. Rodrigues, Ł. Smędowski, and I. Súarez-Ruiz, 2011, Final report on application of reflectance for estimation of structural order working group (Structural WG) 2002-2010: International Committee for Coal and Organic Petrology, ICCP News, No. 52, p. 13-17.Pusz, S., M. Krzesińska, B. Pilawa, A. Koszorek, and R. Buszko, 2010, The dependence of physical structure of a coal heated in a coking chamber on non-uniform distribution of a temperature: International Journal of Coal Geology, v. 82, p. 125-131.Pusz, S., M. Krzesińska, Ł. Smędowski, J. Majewska, B. Pilawa, and B. Kwiecińska, 2010, Changes in a coke structure due to reaction with carbon dioxide: International Journal of Coal Geology, v. 81, p. 287-292.Püttmann, W., Y.Z. Sun, and W. Kalkreuth, 1994, Variation of petrological and geochemical compositions in a sequence of humic coals, cannel coals, and oil shales: Energy & Fuels, v. 8, p. 1460-1468.Püttmann, W., Y.Z. Sun, and W. Kalkreuth, 1994, Variation of petrological and geochemical compositions in a sequence of humic coals, cannel coals, and oil shales: Energy & Fuels, v. 8, p. 1460-1468. (bituminite)Qi, H., R. Hu, and Q. Zhang, 2007, Concentration and distribution of trace elements in lignite from the Shengli coalfield, Inner Mongolia, China: Implications on origin of the associated Wulantuga Germanium deposit: International Journal of Coal Geology, v. 71, p. 129-152.Qi, H., R. Hu, and Q. Zhang, 2007, REE geochemistry of the Cretaceous lignite from Wulantuga germanium deposit, inner Mongolia, northeastern China: International Journal of Coal Geology, v. 71, p. 329-344.Qi, L., and J. Gao, 2008, Revisiting platimum group elements of Late Permian coals from western Guizhou Province, SW China: International Journal of Coal Geology, v. 75, p. 189-193.Qian, Z., M. Clarke, and H. Marsh, 1983, Structure of cokes from coals of different rank: Fuel, v. 62, p. 1084-1089.Qin, S., J. Dai, and X. Liu, 2007, The controlling factors of oil and gas generation from coal in the Kuqa Depression of Tarim Basin, China: International Journal of Coal Geology, v. 70, p. 255-263.Qiu, N., H. Li, Z. Jin, and Y. Zhu, 2007, Temperature and time effect on the concentrations of free radicals in coal: evidence from laboratory pyrolysis experiments: International Journal of Coal Geology, v. 69, p. 220-228.Qiu, N., J. Chang, Y. Zuo, J. Wang, and H. Li, 2012, Thermal evolution and maturation of lower Paleozoic source rocks in the Tarim Basin, northwest China: AAPG Bulletin, v. 96, p. 789-821. (equivalent vitrinite reflectance of Cambrian and Middle-Upper Ordovician)Qiu, N., J. Chang, Y. Zuo, J. Wang, and H. Li, 2012, Thermal evolution and maturation of lower Paleozoic source rocks in the Tarim Basin, northwest China: AAPG Bulletin, v. 96, p. 789-821. (see Table 3 for equivalent vitrinite reflectance of Cambrian and Middle-Upper Ordovician from bitumen reflectance)Qu, P., R. Shen, L. Fu, and Z. Wang, 2011, Time delay effect due to pore pressure changes and existence of cleats on borehole stability in coal seam: International Journal of Coal Geology, v. 85, p. 212-218.Querol, X., A. Alastuey, A. Lopez-Soler, F. Plana, E. Mantilla, R. Juan, C.R. Ruiz, and A. La Orden, 1999, Characterization of atmospheric particulates around a coal-fired power station: International Journal of Coal Geology, v. 40, p. 175-188.

Querol, X., J.L. Fernández-Turiel, A. López-Soler, H.W. Hagemann, J. Dehmer, R. Juan, and C. Ruiz, 1991, Distribution of sulfur in coals of the Teruel mining district, Spain: International Journal of Coal Geology, v. 18, p. 327-346.Querol, X., J.L. Fernández-Turiel, and A. López-Soler, 1995, Trace elements in coal and their behaviour during combustion in a large power station: Fuel, v. 74, p. 331-343.

Pratt, T., and M. Mavor, 2005, An overview of coal gas reservoir properties: core holes from Western Interior Coal Region, in B.J. Cardott, ed., Unconventional energy resources in the southern Midcontinent, 2004 symposium: Oklahoma Geological Survey Circular 110, p. 83-103.

Preusse, A., 1997, Coalbed methane in the Ruhr Carboniferous, in M. Podemski, S. Dybova-Jachowicz, K. Jaworowski, J. Jureczka, and R. Wagner, eds., Proceedings of the XIII International Congress on the Carboniferous and Permian: Warsaw, Polish Geological Institute, Prace, v. 157, pt. 2, p. 379-386.

Prior, W.L., 2005, Natural gas potential of Arkansas coals (abstract), in B.J. Cardott, ed., Unconventional energy resources in the southern Midcontinent, 2004 symposium: Oklahoma Geological Survey Circular 110, p. 67.Prior, W.L., and B. White, 2001, Arkansas coal geology and potential for coalbed methane, in Oklahoma coalbed-methane workshop 2001: Oklahoma Geological Survey Open-File Report 2-2001, p. 44-71.

Puri, R., J.C. Evanoff, and M.L. Brugler, 1992, Measurement of coal cleat porosity and relative permeability characteristics, in Coalbed methane: Society of Petroleum Engineers, Reprint Series 35, p. 56-67.

Querol, X., and S. Chenery, 1995, Determination of trace element affinities in coal by laser ablation microprobe-inductively coupled plasma mass spectrometry, in M.K.G. Whateley and D.A. Spears, eds., European coal geology: London, Geological Society Special Publication 82, p. 147-155.

Querol, X., M. Izquierdo, E. Monfort, E. Alvarez, O. Font, T. Moreno, A. Alastuey, X. Zhuang, W. Lu, and Y. Wang, 2008, Environmental characterization of burnt coal gangue banks at Yangquan, Shanxi Province, China: International Journal of Coal Geology, v. 75, p. 93-104.Querol, X., N. Moreno, J.C. Umaña, A. Alastuey, E. Hernández, A. López-Soler, and F. Plana, 2002, Synthesis of zeolites from coal fly ash: an overview: International Journal of Coal Geology, v. 50, p. 413-423.Querol, X., X. Zhuang, O. Font, M. Izquierdo, A. Alastuey, I. Castro, B.L. van Drooge, T. Moreno, J.O. Grimalt, J. Elvira, M. Cabañas, R. Bartroli, J.C. Hower, C. Ayora, F. Plana, and A. López-Soler, 2011, Influence of soil cover on reducing the environmental impact of spontaneous coal combustion in coal waste gobs: a review and new experimental data: International Journal of Coal Geology, v. 85, p. 2-22.

Quick, J.C., 2004, New rules limiting mercury emissions from coal-fired power plants: Utah Geological Survey, Survey Notes, v. 36, no. 3, p. 12-13, 9.Quick, J.C., 2006, Correction to an equation used in Hower et al., 2005a (Int. J. Coal Geol, v. 62 pp. 223-236) and Hower et al., 2005b [Int. J. Coal Geol, v. 63 pp. 205-227]: International Journal of Coal Geology, v. 66, p. 155-156.Quick, J.C., A. Davis, and R. Lin, 1988, Recognition of reactive maceral types by combined fluorescence and reflectance microscopy: Proceedings Ironmaking Conference, v. 47, p. 331-337.Quick, J.C., A. Davis, and R. Lin, 1988, Recognition of reactive maceral types by combined fluorescence and reflectance microscopy: Proceedings Ironmaking Conference, v. 47, p. 331-337.Quick, J.C., and D.A. Wavrek, 1994, Suppressed reflectance vitrinite: recognition and correction (abstract): AAPG Annual Convention, Official Program, v. 3, p. 240.Quick, J.C., and D.C. Glick, 2000, Carbon dioxide from coal combustion: variation with rank of US coal: Fuel, v. 79, p. 803-812.Quick, J.C., and D.E. Tabet, 2003, Suppressed vitrinite reflectance in the Ferron coalbed gas fairway, central Utah: possible influence of overpressure: International Journal of Coal Geology, v. 56, p. 49-67.Quick, J.C., and D.E. Tabet, 2003, Suppressed vitrinite reflectance in the Ferron coalbed gas fairway, central Utah: possible influence of overpressure: International Journal of Coal Geology, v. 56, p. 49-67.Quick, J.C., and T. Brill, 2002, Provincial variation of carbon emissions from bituminous coal: influence of inertinite and other factors: International Journal of Coal Geology, v. 49, p. 263-275.Quick, J.C., T.C. Brill, and D.E. Tabet, 2003, Mercury in US coal—observations using the COALQUAL and ICR data sets: Environmental Geology, v. 43, p. 247-259.Quillinan, S.A., and C.D. Frost, 2014, Carbon isotope characterization of Power River Basin coal bed waters: Key to minimizing unnecessary water production and implications for exploration and production of biogenic gas: International Journal of Coal Geology, v. 126, p. 106-119.Quillinan, S.A., and C.D. Frost, 2014, Carbon isotope characterization of Power River Basin coal bed waters: Key to minimizing unnecessary water production and implications for exploration and production of biogenic gas: International Journal of Coal Geology, v. 126, p. 106-119.Quintero, J.A., S.A. Candela, C.A. Ríos, C. Montes, and C. Uribe, 2009, Spontaneous combustion of the Upper Paleocene Cerrejón Formation coal and generation of clinker in La Guajira Peninsula (Caribbean region of Colombia): International Journal of Coal Geology, v. 80, p. 196-210.Quispe, D., R. Pérez-López, L.F.O. Silva, and J.M. Nieto, 2012, Changes in mobility of hazardous elements during coal combustion in Santa Catarina power plant (Brazil): Fuel, v. 94, p. 495-503.Quispe, D., R. Pérez-López, L.F.O. Silva, and J.M. Nieto, 2012, Changes in mobility of hazardous elements during coal combustion in Santa Catarina power plant (Brazil): Fuel, v. 94, p. 495-503.Rach, N.M., 2004, New rotating magnet ranging systems useful in oil sands, CBM developments: Oil & Gas Journal, v. 102.8, p. 47-49.Rach, N.M., 2006, Stealth ventures drilling for Nova Scotia CBM: Oil & Gas Journal, v. 104, no. 31, p. 46-48.Radke, M., H. Willsch, and M. Teichmuller, 1990, Generation and distribution of aromatic hydrocarbons in coals of low rank: Organic Geochemistry, v. 15, p. 539-563.Radke, M., R. Schaeffer, D. Leythaeuser, and M. Teichmüller, 1980, Composition of soluble organic matter in coals: relation to rank and liptinite fluorescence: Geochimica et Cosmochimica Acta, v. 44, p. 1787-1800.Radke, M., R.G. Schaefer, D. Leythaeuser, and M. Teichmüller, 1980, Composition of soluble organic matter in coals: relation to rank and liptinite fluorescence: Geochimica et Cosmochima Acta, v. 44, p. 1787-1800.Radke, M., R.G. Schaefer, D. Leythaeuser, and M. Teichmuller, 1980, Composition of soluble organic matter in coals: relation to rank and liptinite fluorescence: Geochimica et Cosmochimica Acta, v. 44, p. 1787-1800.Radke, M., R.G. Schaefer, D. Leythaeuser, and M. Teichmüller, 1980, Composition of soluble organic matter in coals: relation to rank and liptinite fluorescence: Geochimica et Cosmochimica Acta, v. 44, p. 1787-1800.

Radlinski, A.P., M. Mastalerz, A.L. Hinde, M. Hainbuchner, H. Rauch, M. Baron, J.S. Lin, L. Fan, and P. Thiyagarajan, 2004, Application of SAXS and SANS in evaluation of porosity, pore size distribution and surface area of coal: International Journal of Coal Geology, v. 59, p. 245-271.Radliński, A.P., T.L. Busbridge, E.M.A. Gray, T.P. Blach, and D.J. Cookson, 2009, Small angle X-ray scattering mapping and kinetics study of sub-critical CO2 sorption by two Australian coals: International Journal of Coal Geology, v. 77, p. 80-89.Rahman, M., and R.R.F. Kinghorn, 1995, A practical classification of kerogens related to hydrocarbon generation: Journal of Petroleum Geology, v. 18, p. 91-102.

Rahmani, R.A., and R.M. Flores, eds., 1984, Sedimentology of coal and coal-bearing sequences: Boston, Blackwell Scientific Publications, International Association of Sedimentologists Special Publication 7, 412 p.Rahmani, R.A., and R.M. Flores, eds., 1984, Sedimentology of coal and coal-bearing sequences: Boston, Blackwell Scientific Publications, International Association of Sedimentologists Special Publication 7, 412 p.Raistrick, A., and C.E. Marshall, 1939, The nature of coal and coal seams: London, English Universitieis Press Ltd., 282 p.

Raju, M.V.B., and G.B. Misra, 1994, Undiscovered unit regional resources of Gondwana coals in India: International Journal of Coal Geology, v. 25, p. 133-144.Ramaswamy, G., 2001, Advances key for coalbed methane: American Oil & Gas Reporter, v. 44, no. 10, p. 71, 73.Ramaswamy, G., 2002, A field evidence for mineral-catalyzed formation of gas during coal maturation: Oil & Gas Journal, v. 100.38, p. 32-36.Ramaswamy, G., 2005, Some fields in India’s North Cambay Basin have oil derived from nearby lignite seams: Oil & Gas Journal, v. 103.10, p. 37-42.

Quick, J.C., 1994, Iso-rank variation of vitrinite reflectance and fluorescence intensity, in P.K. Mukhopadhyay and W.G. Dow, eds., Vitrinite reflectance as a maturity parameter: applications and limitations: American Chemical Society Symposium Series 570, p. 64-75.Quick, J.C., 1994, Iso-rank variation of vitrinite reflectance and fluorescence intensity, in P.K. Mukhopadhyay and W.G. Dow, eds., Vitrinite reflectance as a maturity parameter: applications and limitations: Washington, D.C., American Chemical Society Symposium Series 570, p. 64-75.Quick, J.C., 1994, Iso-rank variation of vitrinite reflectance and fluorescence intensity, in P.K. Mukhopadhyay and W.G. Dow, eds., Vitrinite reflectance as a maturity parameter: applications and limitations: Washington, D.C., American Chemical Society Symposium Series 570, p. 64-75.

Radlinski, A.P., and E.Z. Radlinska, 1999, The microstructure of pore space in coals of different rank, in M. Mastalerz, M. Glikson, and S.D. Golding, eds., Coalbed methane: scientific, environmental and economic evaluation: Boston, Kluwer Academic Publishers, p. 329-365.

Rahmani, R.A., and R.M. Flores, 1984, Sedimentology of coal and coal-bearing sequences of North America: a historical review, in R.A. Rahmani and R.M. Flores, eds., Sedimentology of coal and coal-bearing sequences: Boston, Blackwell Scientific Publications, International Association of Sedimentologists Special Publication 7, p. 3-10.

Rajan, S., and J.K. Raghavan, 1995, Role of coal maceral composition in reducing sulfur dioxide and oxides of nitrogen emissions from pulverized coal flames, in J.A. Pajares andJ.M.D. Tascon, eds., Coal science: New York, Elsevier, Coal Science and Technology 24, v. 2, p. 1815-1818.

Ramaswamy, S., W.B. Ayers, and S.A. Holditch, 2008, Best drilling, completion and stimulation methods for CBM reservoirs: World Oil, v. 229, no. 10, p. 125-132.Rantitsch, G., 1995, Coalification and graphitization of graptolites in the anchizone and lower epizone: International Journal of Coal Geology, v. 27, p. 1-22.Rantitsch, G., A. Bhattacharyya, J. Schenk, and N.K. Lünsdorf, 2014, Assessing the quality of metallurgical coke by Raman spectroscopy: International Journal of Coal Geology, v. 130, p. 1-7.Rao, C.P., and H.J. Gluskoter, 1973, Occurrence and distribution of minerals in Illinois coals: Illinois State Geological Survey Circular 476, 56 p.Rasmussen, B., and R. Buick, 2000, Oily old ores: evidence for hydrothermal petroleum generation in an Archean volcanogenic massive sulfide deposit: Geology, v. 28, p. 731-734. (pyrobitumen)Rathbone, R.F., and A. Davis, 1993, The effects of depositional environment on vitrinite fluorescence intensity: Organic Geochemistry, v. 20, p. 177-186.Rathbone, R.F., and A. Davis, 1993, The effects of depositional environment on vitrinite fluorescence intensity: Organic Geochemistry, v. 20, p. 177-186.Rathbone, R.F., and A. Davis, 1993, The effects of depositional environment on vitrinite fluorescence intensity: Organic Geochemistry, v. 20, p. 177-186.Rathbone, R.F., J.C. Hower, and F.J. Derbyshire, 1993, The application of fluorescence microscopy to coal-derived resid characterization: Fuel, v. 72, p. 1177-1185.

Rawn-Schatzinger, V., D. Arthur, and B. Langhus, 2003, Coalbed natural gas produced water: water rights and treatment technologies: GasTIPS, v. 9, no. 4, p. 13-18. (part 2 of 3)Rawn-Schatzinger, V., D. Arthur, and B. Langhus, 2004, Coalbed natural gas resources: beneficial use alternatives: GasTIPS, v. 10, no. 1, p. 9-14. (part 3 of 3)Ray, S.K., D.C. Panigrahi, and A.K. Varma, 2014, An electro-chemical method for determining the susceptibility of Indian coals to spontaneous heating: International Journal of Coal Geology, v. 128-129, p. 68-80.Raymond, A., 1988, The paleoecology of a coal-ball deposit from the Middle Pennsylvanian of Iowa dominated by Cordaitalean gymnosperms: Review of Palaeobotany and Palynology, v. 53, p. 233-250.Raymond, A., L. Lambert, S. Costanza, E.J. Stone, and P.C. Cutlip, 2010, Cordaiteans in paleotropical wetlands: an ecological re-evaluation: International Journal of Coal Geology, v. 83, p. 248-265.

Raymond, A., R. Guillemette, C.P. Jones, and W.M. Ahr, 2012, Carbonate petrology and geochemistry of Pennsylvanian coal balls from the Kalo Formation of Iowa: International Journal of Coal Geology, v. 94, p. 137-149.Raymond, A., R. Guillemette, C.P. Jones, and W.M. Ahr, 2012, Carbonate petrology and geochemistry of Pennsylvanian coal balls from the Kalo Formation of Iowa: International Journal of Coal Geology, v. 94, p. 137-149.Raymond, A., R. Guillemette, C.P. Jones, and W.M. Ahr, 2012, Carbonate petrology and geochemistry of Pennsylvanian coal balls from the Kalo Formation of Iowa: International Journal of Coal Geology, v. 94, p. 137-149.Raymond, A.C., and D.G. Murchison, 1991, Influence of exinitic macerals on the reflectance of vitrinite in Carboniferous sediments of the Midland Valley of Scotland: Fuel, v. 70, p. 155-161.Raymond, A.C., and D.G. Murchison, 1991, Influence of exinitic macerals on the reflectance of vitrinite in Carboniferous sediments of the Midland Valley of Scotland: Fuel, v. 70, p. 155-161.Raymond, A.C., and D.G. Murchison, 1991, The relationship between organic maturation, the widths of thermal aureoles and the thicknesses of sills in the Midland Valley of Scotland and northern England: Journal of the Geological Society, London, v. 148, pt. 2, p. 215-218.Raymond, A.C., and D.G. Murchison, 1992, Effect of igneous activity on molecular-maturation indices in different types of organic matter: Organic Geochemistry, v. 18, p. 725-735.

Raynaud, J.-F., and P. Robert, 1976, Les methodes d'etude optique de la matiere organique: Bull. Centre Rech. Pau - SNPA, v. 10, p. 109-127.Raynaud, J.-F., B. Lugardon, and G. Lacrampe-Couloume, 1988, Observation de membranes fossiles dans la matiere organique "amorphe" de roches meres de petrole: C.R. Acad. Sci. Paris, v. 307, Series II, p. 1703-1709.Raynaud, J.-F., B. Lugardon, and G. Lacrampe-Couloume, 1989, Lamellar structures and bacteria as main components of the amorphous matter of source rocks: Bulletin Centres Recherches Exploration-Production, Elf Aquitaine, v. 13, p. 1-21.Razvigorova, M., T. Budinova, B. Tsyntsarski, B. Petrova, E. Ekinci, and H. Atakul, 2008, The composition of acids in bitumen and in products from saponification of kerogen: Investigation of their role as connecting kerogen and mineral matrix: International Journal of Coal Geology, v. 76, p. 243-249.Razzaq, R., C. Li, and S. Zhang, 2013, Coke oven gas: Availability, properties, purification, and utilization in China: Fuel, v. 113, p. 287-299.Reaugh, A.B., and G.S. Bayliss, 1980, Fluorescence of acritarchs in study of marine kerogen (abstract): AAPG Bulletin, v. 64, p. 770.Reddy, K.J., C. Helmericks, A. Whitman, and D. Legg, 2014, Geochemical processes controlling trace elemental mobility in coalbed natural gas (CBNG) disposal ponds in the Powder River Basin, WY: International Journal of Coal Geology, v. 126, p. 120-127Reddy, K.J., C. Helmericks, A. Whitman, and D. Legg, 2014, Geochemical processes controlling trace elemental mobility in coalbed natural gas (CBNG) disposal ponds in the Powder River Basin, WY: International Journal of Coal Geology, v. 126, p. 120-127.Reed, F.D., 1926, Flora of an Illinois coal ball: Botanical Gazette, v. 81, p. 460-468.

Rees, O.W. and E.D. Pierron, 1954, Plastic and swelling properties of Illinois coals: Illinois State Geological Survey Circular 190, 11 p.Rees, O.W., 1964, Composition of the ash of Illinois coal: Illinois State Geological Survey Circular 365, 20 p.Rees, O.W., 1966, Chemistry, uses, and limitations of coal analyses: Illinois State Geological Survey Report of Investigation 220, 55 p.Rees, O.W., F.A. Coolican, and E.D. Pierron, 1957, Comparison of methods for determination of volatile matter and ash in coal: Illinois State Geological Survey Circular 240, 8 p.Rees, O.W., F.C. Coolican, E.D. Pierron, and C.W. Beeler, 1961, Effects of outdoor storage on Illinois steam coals: Illinois State Geological Survey Circular 313, 10 p.Rees, O.W., N.F. Shimp, C.W. Beeler, J.K. Kuhn, and R.J. Helfinstine, 1966, Sulfur retention in bituminous coal ash: Illinois State Geological Survey Circular 396, 10 p.Reese, S.O., and O.C. Kopp, 1990, Effect of paleotopography on the composition of a Hazard coal zone, Pocahonta Basin, eastern Kentucky: Journal of Coal Quality, v. 9, p. 71-76.

Rawat, M.S., and C.M. Berry, 1989, Palynofacies, maturation and source rock potential in Krishna-Godavari basin, India, in K.P. Jain and R.S. Tiwari, eds., Proceedings of the symposium on vistas in Indian palaeobotany: Palaeobotanist, v. 38, p. 180-187.

Raymond, A., P.C. Cutlip, and M. Sweet, 2001, Rates and processes of terrestrial nutrient cycling in the Paleozoic: the world before beetles, termites, and flies, in W.D. Allmon and D.J. Bottjer, eds., Evolutionary paleoecology: the ecological context of macroevolutionary change: New York, Columbia University Press, p. 235-283.

Raymond, R., Jr., 1982, Electron Probe microanalysis—a means of direct determination of organic sulfur in coal, in E.L. Fuller, Jr., ed., Coal and coal products: analytical characterization techniques: American Chemical Society ACS Symposium Series 205, p. 191-203.

Reed, F.H., H.W. Jackman, O.W. Rees, G.R. Yohe, and P.W. Henline, 1947, Use of Illinois coal for production of metallurgical coke: Illinois State Geological Survey, Bulletin 71, 132 p. http://library.isgs.uiuc.edu/Pubs/pdfs/bulletins/bul071.pdf

Reeves, S., 2002, Field studies of enhanced methane recovery and CO2 sequestration in coal seams: World Oil, v. 223, no. 12, p. 56-58, 60.

Reeves, S.R., 2003, Enhanced CBM recovery, coalbed CO2 sequestration assessed: Oil & Gas Journal, v. 101.27, p. 49-53.Regtop, R.A., P.T. Crisp, and J. Ellis, 1982, Chemical characterization of shale oil from Rundle, Queensland: Fuel, v. 61, p. 185-192.Reidenouer, D., E.G. Williams, and R.R. Dutcher, 1967, The relationship between paleotopography and sulfur distribution in some coals of western Pennsylvania: Economic Geology, v. 62, p. 632-647.Reifenstein, A.P., O.C. Roberts, J.E. Eberhardt, and T.H. Nguyen, 1994, Macroscopic and microscopic fluorescence spectra of coal and coal components: International Journal of Coal Geology, v. 26, p. 79-94.

Remington, N.C., 1959, A history of the gilsonite industry: Salt Lake City, University of Utah, unpublished M.S. thesis, 338 p.Rentel, K., 1987, The combined maceral-microlithotype analysis for the characterization of reactive inertinites: International Journal of Coal Geology, v. 9, p. 77-86.Rentel, K., 1987, The combined maceral-microlithotype analysis for the characterization of reactive inertinites: International Journal of Coal Geology, v. 9, p. 77-86.

Renton, J.J., and D.S. Bird, 1991, Association of coal macerals, sulfur, sulfur species and the iron disulphide minerals in three columns of the Pittsburgh coal: International Journal of Coal Geology, v. 17, p. 21-50.Renton, J.J., and D.S. Bird, 1991, Association of coal macerals, sulfur, sulfur species and the iron disulphide minerals in three columns of the Pittsburgh coal: International Journal of Coal Geology, v. 17, p. 21-50.

Retallack, G.J., J.J. Veevers, and R. Morante, 1996, Global coal gap between Permian-Triassic extinction and Middle Triassic recovery of peat-forming plants: Geological Society of America Bulletin, v. 108, p. 195-207.Reucroft, P.J., and A.R. Sethuraman, 1987, Effect of pressure on carbon dioxide induced coal swelling: Energy and Fuels, v. 1, p. 72-75.Reucroft, P.J., and A.R. Sethuraman, 1987, Effect of pressure on carbon dioxide induced coal swelling: Energy Fuels, v. 1, p. 72-75.Reucroft, P.J., and K.B. Patel, 1986, Surface area and swelling in coal: Fuel, v. 62, p. 279-284.

Rhoads, C.A., J.T. Senftle, M.M. Coleman, A. Davis, and P.C. Painter, 1983, Further studies of coal oxidation: Fuel, v. 62, p. 1387-1392.Rhodes, Q.Z., II, 2008, O2 removal key to Tower mine project: American Oil & Gas Reporter, v. 51, no. 6, p. 132-139.Ribeiro, J., B. Valentim, C. Ward, and D. Flores, 2011, Comprehensive characterization of anthracite fly ash from a thermo-electric power plant and its potential environmental impact: International Journal of Coal Geology, v. 86, p. 204-212.Ribeiro, J., E. Ferreira da Silva, and D. Flores, 2010, Burning of coal waste piles from Douro Coalfield (Portugal): petrological, geochemical and mineralogical characterization: International Journal of Coal Geology, v. 81, p. 359-372.Ribeiro, J., E. Ferreira da Silva, Z. Li, C. Ward, and D. Flores, 2010, Petrographic, mineralogical and geochemical characterization of the Serrinha coal waste pile (Douro coalfield, Portugal) and the potential environmental impacts on soil, sediments and surface waters: International Journal of Coal Geology, v. 83, p. 456-466.Ribeiro, J., E.Ferreira da Silva, A. Pinto de Jesus, and D. Flores, 2011, Petrographic and geochemical characterization of coal waste piles from Douro coalfield: International Journal of Coal Geology, v. 87, p. 226-236.

Ribeiro, J., S.R. Taffarel, C.H. Sampaio, D. Flores, and L.F.O. Silva, 2013, Mineral speciation and fate of some hazardous contaminants in coal waste pile from anthracite mining in Portugal: International Journal of Coal Geology, v. 109-110, p. 15-23.Ribeiro, J., T.F. Silva, J.G. Mendonça Filho, and D. Flores, 2012, Polycyclic aromatic hydrocarbon (PAHs) in burning and non-burning coal waste material: Journal of Hazardous Materials, v. 199-200, p. 105-110.Ribeiro, J., T.F. Silva, J.G. Mendonça Filho, and D. Flores, 2014, Fly ash from coal combustion — An environmental source of organic compounds: Applied Geochemistry, v. 44, p. 103-110.Riboulleau, A., S. Derenne, C. Largeau, and F. Baudin, 2001, Origin of contrasting features and preservation pathways in kerogens from the Kashpir oil shales (Upper Jurassic, Russian Platform): Organic Geochemistry, v. 32, p. 647-665.Rice, C.A., 2003, Production waters associated with the Ferron coalbed methane fields, central Utah: chemical and isotopic composition and volumes: International Journal of Coal Geology, v. 56, p. 141-169.Rice, C.A., 2003, Production waters associated with the Ferron coalbed methane fields, central Utah: chemical and isotopic composition and volumes: International Journal of Coal Geology, v. 56, p. 141-169.

Reeves, S., 2001, Geologic sequestration of CO2 in deep, unmineable coalbeds: an integrated research and commercial-scale demonstration project: National Energy Technology Laboratory First National Conference on Carbon Sequestration. http://www.netl.doe.gov/publications/proceedings/01/carbon_seq/3a1.pdfReeves, S., 2001, Geologic sequestration of CO2 in deep, unmineable coalbeds: an integrated research and commercial-scale demonstration project: National Energy Technology Laboratory, First National Conference on Carbon Sequestration. http://www.netl.doe.gov/publications/proceedings/01/carbon_seq/3a1.pdf

Reeves, S., 2002, Field studies of enhanced methane recovery and CO2 sequestration in coal seams: World Oil, v. 223, no. 12, p. 56-58, 60. http://www.worldoil.com/magazine/MAGAZINE_DETAIL.asp?ART_ID=1906&MONTH_YEAR=DEC-2002

Reinecke, K.M., D.D. Rice, and R.C. Johnson, 1991, Characteristics and development of fluvial sandstone and coalbed reservoirs of Upper Cretaceous Mesaverde Group, Grand Valley field, Colorado, in S.D. Schwochow, D.K. Murray, and M.F. Fahy, eds., Coalbed methane of western North America: Denver, CO, Rocky Mountain Association of Geologists Guidebook, p. 209-225.

Renton, J.J., 1979, The mineral matter of coal, in A.C. Donaldson, M.W. Presley, and J.J. Renton, eds., Carboniferous coal short course and guidebook: West Virginia Geological and Economic Survey, Bulletin B-37-1, p. 189-205.Renton, J.J., 1982, Mineral matter in coal, in R.A. Meyers, ed., Coal structure: New York, Academic Press, p. 283-326.Renton, J.J., and C.B. Cecil, 1979, The origin of mineral matter in coal, in A.C. Donaldson, M.W. Presley, and J.J. Renton, eds., Carboniferous coal short course and guidebook: West Virginia Geological and Economic Survey, Bulletin B-37-1, p. 206-223.

Repetski, J.E., R.T. Ryder, D.J. Weary, A.G. Harrris, and M.H. Trippi, 2008, Thermal maturity patterns (CAI and %Ro) in Upper Ordovician and Devonian rocks of the Appalachian Basin: a major revision of USGS Map I-917-E using new subsurface collections: U.S. Geological Survey Scientific Investigations Map 3006, one CD-ROM. http://pubs.usgs.gov/sim/3006/Repetski, J.E., R.T. Ryder, D.J. Weary, A.G. Harrris, and M.H. Trippi, 2008, Thermal maturity patterns (CAI and %Ro) in Upper Ordovician and Devonian rocks of the Appalachian Basin: a major revision of USGS Map I-917-E using new subsurface collections: U.S. Geological Survey Scientific Investigations Map 3006, one CD-ROM. http://pubs.usgs.gov/sim/3006/

Rhoades, A.H., R.J. Gray, and H.D. Huntington, 1981, Application of microscopic techniques in the evaluation of coal-coke and related products, in D.M. Hansen, and W.C. Parks, eds., Process mineralogy: Chicago, IL, Proceedings of a symposium at the 110 th American Institute of Mechanical Engineers Annual Meeting, p. 453-478.

Ribeiro, J., R. Moura, D. Flores, D.B. Lopes, C. Gouveia, S. Mendonça, and O. Frazão, 2013, The Douro coalfield fires of Portugal, in G.B. Stracher, A. Prakash, and E.V. Sokol, eds., Coal and peat fires: A global perspective: Elsevier, Coal-fire atlas of the world, v. 2, p. 313-337.

Rice, C.A., and V. Nuccio, 2000, Water produced with coal-bed methane: U.S. Geological Survey, Fact Sheet FS-156-00, 2 p. (http://pubs.usgs.gov/products/books/factsheet/2000.html)Rice, C.A., and V. Nuccio, 2000, Water produced with coal-bed methane: U.S. Geological Survey, Fact Sheet FS-156-00, 2 p. (http://pubs.usgs.gov/products/books/factsheet/2000.html)Rice, C.A., M.S. Ellis, and J.H. Bullock, Jr., 2000, Water co-produced with coalbed methane in the Powder River basin, Wyoming: preliminary compositional data: U.S. Geological Survey Open-File Report 00-372, 18 p. (http://greenwood.cr.usgs.gov/energy/CBmethane/OF00-372/index.html)Rice, C.A., M.S. Ellis, and J.H. Bullock, Jr., 2000, Water co-produced with coalbed methane in the Powder River basin, Wyoming: preliminary compositional data: U.S. Geological Survey Open-File Report 00-372, 18 p. (http://greenwood.cr.usgs.gov/energy/CBmethane/OF00-372/index.html)

Rice, C.A., R.M. Flores, G.D. Stricker, and M.S. Ellis, 2008, Chemical and stable isotopic evidence for water/rock interaction and biogenic origin of coalbed methane, Fort Union Formation, Powder River Basin, Wyoming and Montana U.S.A.: International Journal of Coal Geology, v. 76, p. 76-85.

Rice, D.D., 1997, Coalbed methane—an untapped energy resource and an environmental concern: U.S. Geological Survey, Fact Sheet FS-019-97.

Rice, D.D., J.L. Clayton, and M.J. Pawlewicz, 1989, Characterization of coal-derived hydrocarbons and source-rock potential of coal beds, San Juan basin, New Mexico and Colorado, U.S.A.: International Journal of Coal Geology, v. 13, p. 597-626.Rice, D.D., J.L. Clayton, R.M. Flores, B.E. Law, and R.W. Stanton, 1992, Some geologic controls of coalbed gas generation, accumulation, and production, western United States: U.S. Geological Survey Circular 1074.Rich, F.J., and W. Spackman, 1979, Modern and ancient pollen sedimentation around tree islands in the Okefenokee Swamp: Palynology, v. 3, p. 219-226.Richardson, A.R., C.F. Eble, J.C. Hower, and J.M.K. O’Keefe, 2012, A critical re-examination of the petrology of the No. 5 Block coal in eastern Kentucky with special attention to the origin of inertinite macerals in the splint lithotypes: : International Journal of Coal Geology, v. 98, p. 41-49.Richardson, C., 1910, Grahamite, a solid native bitumen: American Chemical Society Journal, v. 32, p. 1032-1049.

Rickert, D.A., W.J. Ulman, and E.R. Hampton, eds., 1979, Synthetic fuels development: earth-science considerations: U.S. Geological Survey, 45 p.Riding, J., and S. Warny, eds., 2008, Palynological techniques by C.A. Brown (second edition): AASP Foundation, The Palynological Society, 146 p.Riding, J.B., and J.E. Kyffin-Hughes, 2011, A direct comparison of three palynological preparation techniques: Review of Palaeobotany and Palynology, v. 167, p. 212-221.Rieb, B., 2006, Proppants raise the curve for coalbed methane production: World Oil, v. 226, no. 8, p. 71-74.Rieder, M., J.C. Crelling, O. Šustai, M. Drábek, Z. Weiss, and M. Klementová, 2007, Arsenic in iron disulfides in a brown coal from the North Bohemian Bsain, Czech Republic: International Journal of Coal Geology, v. 71, p. 115-121.Riediger, C., F. Goodarzi, and R.W. Macqueen, 1989, Graptolites as indicators of regional maturity in lower Paleozoic sediments, Selwyn basin, Yukon and Northwest Territories, Canada: Canadian Journal of Earth Sciences, v. 26, p. 2003-2015.Riediger, C.L., 1993, Solid bitumen reflectance and Rock-Eval Tmax as maturation indices: an example from the "Nordegg member", western Canada sedimentary basin: International Journal of Coal Geology, v. 22, p. 295-315.Riediger, C.L., 1993, Solid bitumen reflectance and Rock-Eval Tmax as maturation indices: an example from the "Nordegg member", western Canada sedimentary basin: International Journal of Coal Geology, v. 22, p. 295-315.

Riepe, W., and M. Steller, 1987, Relationship between reflectance distribution and hydrogenation behavior of hard coals: Fuel, v. 66, p. 83-85.Riepe, W., M. Steller, and C.H. Hilgers, 1988, Characterizations of coal and coal blends by an automatic scanning photometer: Erdol und Kohle-Erdgas-Petrochemie, v. 41, p. 216-218.

Riestenberg, D., R. Ferguson, and V.A. Kuuskraa, 2007, Unconventional gas—3. New plays, prospects, resources continue to emerge: Oil & Gas Journal, v. 105.36, p. 48-54.

Rightmire, C.T., G.E. Eddy, and J.N. Kirr, eds., 1984, Coalbed methane resources of the United States: AAPG Studies in Geology 17, 378 p.

Riley, K.W., D.H. French, N.A. Lambropoulos, O.P. Farrell, R.A. Wood, and F.E. Huggins, 2007, Origin and occurrence of selenium in some Australian coals: International Journal of Coal Geology, v. 72, p. 72-80.Riley, K.W., D.H. French, O.P. Farrell, R.A. Wood, and F.E. Huggins, 2012, Modes of occurrence of trace and minor elements in some Australian coals: International Journal of Coal Geology, v. 94, p. 214-224.Rimmer, S. M., and A. Davis, 1988, Influence of depositional environments on coal petrographic composition in the Lower Kittanning seam, western Pennsylvania: Organic Geochemistry, v. 12, p. 375-387Rimmer, S. M., and A. Davis, 1988, Influence of depositional environments on coal petrographic composition in the Lower Kittanning seam, western Pennsylvania: Organic Geochemistry, v. 12, p. 375-387Rimmer, S.M., 1991, Distributions and associations of selected trace elements in the Lower Kittanning seam, western Pennsylvania, U.S.A.: International Journal of Coal Geology, v. 17, p. 189-212.Rimmer, S.M., D.F. Bensley, and J.C. Crelling, 1989, Fluorescence spectral analysis of sporinite in the Lower Kittanning coal bed: Organic Geochemistry, v. 14, p. 343-350.Rimmer, S.M., D.J. Cantrell, and P.J. Gooding, 1993, Rock-Eval pyrolysis and vitrinite reflectance trends in the Cleveland Shale member of the Ohio Shale, eastern Kentucky: Organic Geochemistry, v. 20, p. 735-745.Rimmer, S.M., D.J. Cantrell, and P.J. Gooding, 1993, Rock-Eval pyrolysis and vitrinite reflectance trends in the Cleveland Shale Member of the Ohio Shale, eastern Kentucky: Organic Geochemistry, v. 20, p. 735-745.

Rice, C.A., T.T. Bartos, and M.S. Ellis, 2002, Chemical and isotopic composition of water in the Fort Union and Wasatch Formations of the Powder River basin, Wyoming and Montana: implications for coalbed methane development, in S.D. Schwochow and V.F. Nuccio, eds., Coalbed methane of North America, II: Rocky Mountain Association of Geologists, p. 53-70.Rice, C.A., T.T. Bartos, and M.S. Ellis, 2002, Chemical and isotopic composition of water in the Fort Union and Wasatch Formations of the Powder River basin, Wyoming and Montana: implications for coalbed methane development, in S.D. Schwochow and V.F. Nuccio, eds., Coalbed methane of North America, II: Rocky Mountain Association of Geologists, p. 53-70.Rice, D.D., 1993, Composition and origins of coalbed gas, in B.E. Law and D.D. Rice, eds., Hydrocarbons from coal: AAPG Studies in Geology 38, p. 159-184.Rice, D.D., 1996, Geologic framework and description of coalbed gas plays, in D.L. Gautier and others, eds., 1995 National assessment of United States oil and gas resources -- results, methodology, and supporting data: U.S. Geological Survey Digital Data Series DDS-30, release 2, CD-ROM.

Rice, D.D., B.E. Law, and J.L. Clayton, 1993, Coalbed gas - an undeveloped resource, in D.G. Howell, ed., The future of energy gases: USGS Professional Paper 1570, p. 389-404.Rice, D.D., G.B.C. Young, and G.W. Paul, 1996, Methodology for assessment of technically recoverable resources of coalbed gas, in D.L. Gautier and others, eds., 1995 National assessment of United States oil and gas resources -- results, methodology, and supporting data: U.S. Geological Survey Digital Data Series DDS-30, release 2, CD-ROM.Rice, D.D., J.L. Clayton, and M.J. Pawlewicz, 1989, Characterization of coal-derived hydrocarbons and source rock potential of coal beds, San Juan basin, New Mexico and Colorado, USA, in P.C. Lyons and B. Alpern, eds., Coal: classification, coalification, mineralogy, trace-element chemistry, and oil and gas potential: International Journal of Coal Geology, v. 13, p. 597-626.

Richardson, R.J.H., 1991, Coal resources and coalbed methane potential of a major Alberta coal zone, in S.D. Schwochow, D.K. Murray, and M.F. Fahy, eds., Coalbed methane of western North America: Denver, CO, Rocky Mountain Association of Geologists Guidebook, p. 255-263.

Rieke, H.H., and J.N. Kirr, 1984, Geologic overview, coal, and coalbed methane resources of the Arkoma basin - Arkansas and Oklahoma, in C.T. Rightmire, G.E. Eddy, and J.N. Kirr, eds., Coalbed methane resources of the United States: AAPG Studies in Geology 17, p. 135-161.Rieke, H.H., and J.N. Kirr, 1984, Geologic overview, coal, and coalbed methane resources of the Wind River Basin—Wyoming, in C.T. Rightmire, G.E. Eddy, and J.N. Kirr, eds., Coalbed methane resources of the United States: AAPG Studies in Geology 17, p. 295-334.

Riese, W.C., W.L. Pelzmann, and G.T. Snyder, 2005, New insights on the hydrocarbon system of the Fruitland Formation coal beds, northern San Juan Basin, Colorado and New Mexico, USA, in P.D. Warwick, ed., Coal systems analysis: Geological Society of America Special Paper 387, p. 73-111.

Rightmire, C.T., 1984, Coalbed methane resource, in C.T. Rightmire, G.E. Eddy, and J.N. Kirr, eds., Coalbed methane resources of the United States: AAPG Studies in Geology 17, p. 1-13.Rightmire, C.T., and R. Choate, 1986, Coal-bed methane and tight gas sands interrelationships, in C.W. Spencer and R.F. Mast, eds., Geology of tight gas reservoirs: AAPG Studies in Geology 24, p. 87-110.

Riley, J.T., G.M. Ruba, and C.C. Lee, 1990, Direct determination of total organic sulfur in coal, in W.L. Orr and C.M. White, eds., Geochemistry of sulfur in fossil fuels: Washington, D.C., American Chemical Society ACS Symposium Series 429, p. 231-240.

Rimmer, S.M., L.E. Yoksoulian, and J.C. Hower, 2009, Anatomy of an intruded coal, I: Effect of contact metamorphism on whole-coal geochemistry, Springfield (No. 5)(Pennsylvanian) coal, Illinois Basin: International Journal of Coal Geology, v. 79, p. 74-82.Rimmer, S.M., L.E. Yoksoulian, and J.C. Hower, 2009, Anatomy of an intruded coal, I: Effect of contact metamorphism on whole-coal geochemistry, Springfield (No. 5)(Pennsylvanian) coal, Illinois Basin: International Journal of Coal Geology, v. 79, p. 74-82.Risser, H.E., 1968, Gasification and liquefaction: their potential impact on various aspects of the coal industry: Illinois State Geological Survey, Circular 430, 28 p.Ritter, U., and A. Grover, 2005, Adsorption of petroleum compounds in vitrinite: implications for petroleum expulsion from coal: International Journal of Coal Geology, v. 62, p. 183-191.Ritter, U., and A. Grover, 2005, Adsorption of petroleum compounds in vitrinite: implications for petroleum expulsion from coal: International Journal of Coal Geology, v. 62, p. 183-191.Ritter, U., and A. Grover, 2005, Adsorption of petroleum compounds in vitrinite: implications for petroleum expulsion from coal: International Journal of Coal Geology, v. 62, p. 183-191.Rivera-Utrilla, J., M.A. Ferro-Garcia, F.J. Maldonado-Hodar, and A.M. Mastral-Lamarca, 1994, Influence of the porous texture of coals on their hydrogenation processes. I. Physical characteristics of coals: Journal of Coal Quality, v. 13, p. 46-51.

Robert, P., 1979, Classification des matieres organiques en fluorescence application aux roches-meres petroliers: Bulletin Centres Recherches Exploration-Production, Elf Aquitaine, v. 3, p. 223-263.

Robert, P., 1981, Classification of organic matter by means of fluorescence; application to hydrocarbon source rocks: International Journal of Coal Geology, v. 1, p. 101-137.Robert, P., 1988, Organic metamorphism and geothermal history: Boston, Elf-Aquitaine and D. Reidel Publishing Company, 311 p.Robert, P., 1988, Organic metamorphism and geothermal history: Boston, Kluwer Academic Publishers, 311 p.Robert, P., 1988, Organic metamorphism and geothermal history: microscopic study of organic matter and thermal evolution of sedimentary basins: Norwell, MA, Kluwer Academic Publishers, 311 p. (see p. 102-105).Roberts, D.L., 1991, The inherent moisture content of South African Permian coals: International Journal of Coal Geology, v. 17, p. 297-311.Roberts, L.N., and P.J. McCabe, 1992, Peat accumulation in coastal-plain mires; a model for coals of the Fruitland Formation (Upper Cretaceous) of southern Colorado, USA: International Journal of Coal Geology, v. 21, p. 115-138.Roberts, S., P.M. Tricker, and J.E.A. Marshall, 1995, Raman spectroscopy of chitinozoans as a maturation indicator: Organic Geochemistry, v. 23, p. 223-228.

Roberts, S.B., R.W. Stanton, and R.M. Flores, 1994, A debris flow deposit in alluvial, coal-bearing facies, Bighorn Basin, Wyoming, USA: evidence for catastrophic termination of a mire: International Journal of Coal Geology, v. 25, p. 213-241.Roberts-Ashby, T.L., M.T. Stewart, and B.N. Ashby, 2013, An evaluation of porosity and potential use for carbon dioxide storage in the Upper Cretaceous Lawson Formation and Paleocene Cedar Keys Formation of south-central and southern Florida: Environmental Geosciences Journal, v. 20, no. 3.Roberts-Ashby, T.L., S.T. Brennan, M.L. Buursink, J.A. Covault, W.H. Craddock, R.M. Drake II, M.D. Merrill, E.R. Slucher, P.D. Warwick, M.S. Blondes, M.A. Gosai, P.A. Freeman, S.M. Cahan, C.A. DeVera, and C.D. Lohr, 2012, Geologic framework for the national assessment of carbon dioxide storage resources—U.S. Gulf Coast: U.S. Geological Survey Open-File Report 2012-1024-H, 77 p.Robertson, E.P., 2009, Economic analysis of carbon dioxide sequestration in Powder River Basin coal: International Journal of Coal Geology, v. 77, p. 234-241.

Robinson, B.M., and S.A. Holditch, 1999, Coal gas requires unique stimulation: American Oil & Gas Reporter, v. 42, no. 12, p. 64, 66-68, 79.Robinson, H.M., 1916, Ozokerite in central Utah: U.S. Geological Survey Bulletin 641-A, 16 p.Robinson, J.W., 1983, Co-carbonization of selected American coals with commercial additives: International Journal of Coal Geology, v. 2, p. 279-296.Robinson, K.K., and D.F. Tatterson, 2007, Fischer-Tropsch oil-from-coal promising as transport fuel: Oil & Gas Journal, v. 105.8, p. 20-31.Robinson, K.K., and D.F. Tatterson, 2008, Economics on Fischer-Tropsch coal-to-liquids method updated: Oil & Gas Journal, v. 106.40, p. 22-26.

Robison, C.R., 1997, Hydrocarbon source rock variability within the Austin Chalk and Eagle Ford Shale (Upper Cretaceous), east Texas, U.S.A.: International Journal of Coal Geology, v. 34, p. 287-305.

Robl, T.L., and B.H. Davis, 1993, Comparison of the HF-HCl and HF-BF3 maceration techniques and the chemistry of resultant organic concentrates: Organic Geochemistry, v. 20, p. 249-255.

Robl, T.L., D.N. Taulbee, L.S. Barron, and W.C. Jones, 1987, Petrologic chemistry of a Devonian Type II kerogen: Energy Fuels, v. 1, p. 507-513.

Rodrigues, C.F., and M.J. Lemos de Sousa, 2002, The measurement of coal porosity with different gases: International Journal of Coal Geology, v. 48, p. 245-251.Rodrigues, S., I. Suárez-Ruiz, M. Marques, and D. Flores, 2012, Catalytic role of mineral matter in structural transformation of anthracites during high temperature treatment: International Journal of Coal Geology, v. 93, p. 49-55.Rodrigues, S., M. Marques, C.R. Ward, I. Suárez-Ruiz, and D. Flores, 2012, Mineral transformations during high temperature treatment of anthracite: International Journal of Coal Geology, v. 94, p. 191-200.Rodriguez, R., 1987, Characterization of coal seams by seismic methods: Lexington, KY, Institute for Mining and Minerals Research, IMMR86/107, 19 p.

Robbins, G.A., 1991, Coal structure, the problem with minerals, in H.H. Schobert, K.D. Bartle, and L.J. Lynch, eds., Coal science II: Washington, D.C., American Chemical Society, ACS Symposium Series 461, p. 44-60.

Robert, P., 1980, The optical evolution of kerogen and geothermal histories applied to oil and gas exploration, in B. Durand, ed., Kerogen - insoluble organic matter from sedimentary rocks: Paris, Editions Technip, p. 385-414.

Roberts, S.B., compiler, 2008, Geologic assessment of undiscovered, technically recoverable coalbed-gas resources in Cretaceous and Tertiary rocks, North Slope and adjacent state waters, Alaska: U.S. Geological Survey Digital Data Series DDS-69-S, CD-ROM. http://pubs.usgs.gov/dds/dds-069/dds-069-s/OPEN_FIRST/OPEN_FIRST.pdf

Robertson, R.D., 2003, A frontier Upper Cretaceous coalbed methane play in the Albuquerque Basin, New Mexico, in M.R. Silverman, ed., Emerging coalbed methane plays of North America (part 3): Petroleum Frontiers, v. 19, no. 2, p. 20-30.

Robinson, W.E., 1969, Isolation procedures for kerogens and associated soluble organic matter, in G. Eglinton and M.T.J. Murphy, eds., Organic geochemistry: New York, Springer-Verlag, p. 181-195.

Robl, T., J.G. Groppo, S. Brooks, J.C. Hower, and S.S. Medina, 1995, Case studies of low Nox burner retrofit: 1. The effect of loss on ignition, particle size, and chemistry of the fly ash, in S.S. Tyson, T.H. Blackstock, J. Hunger, and A. Marshall, eds., Proceedings: 11 th International symposium on use and management of coal combustion by-products (CCBs): American Coal Ash Association, o. 21-1 to 21-12.

Robl, T.L., and D.N. Taulbee, 1995, Demineralization and kerogen maceral separation and chemistry, in C. Snape, ed., Composition, geochemistry and conversion of oil shales: Boston, Kluwer Academic Publishers, NATO ASI Series C, Mathematical and Physical Sciences, v. 455, p. 35-50.Robl, T.L., and D.N. Taulbee, 1995, Demineralization and kerogen maceral separation and chemistry, in C. Snape, ed., Composition, geochemistry and conversion of oil shales: Boston, Kluwer Academic Publishers, NATO ASI Series C, Mathematical and Physical Sciences, v. 455, p. 35-50.

Robl, T.L., J.C. Hower, U.M. Graham, R.F. Rathbone, and S.S. Medina, 1995, Influence of conversion to low Nox combustion on fly ash petrography and mineralogy: a cae study, in S.-H. Chiang, ed., Proceedings: Coal — energy and the environment: Twelfth Annual International Pittsburgh Coal Conference, p. 121-125.Rochdi, A., P. Landais, and A. Burneau, 1991, Analysis of coal by transmission FTIR microspectroscopy: methodological aspect, in P. Bertrand, ed., Coal: formation, occurrence and related properties: Bulletin de la Societe Geologique de France, v. 162, p. 155-162.

Rodvelt, G., M. Blauch, R.D. Rickman, J.A. Ringhisen, L.E. East, and G. Wylie, 2008, Unconventional gas technology—conclusion. Life-cycle approach improves coalbed methane production: Oil & Gas Journal, v. 106.3, p. 55-60.Rodvelt, G., S. Willis, D. Mullins, and R. Toothman, 2002, CT fracturing: multiple coals, one trip: American Oil & Gas Reporter, v. 45, no. 5, p. 83-87.

Rogers, M.A., J.D. McAlary, and N.J.L. Bailey, 1974, Significance of reservoir bitumens to thermal-maturation studies, Western Canada Basin: AAPG Bulletin, v. 5, p. 1806-1824.Rogers, M.P., M. Rinehart, and D. Forster, 1977, A bibliography of publications dealing with oil shale and shale oil from U.S. Bureau of Mines, 1917-1974, and the Era Laramie Energy Research Center, 1975-1976: U.S. Energy Research and Development Administration, Laramie Energy Research Center, 51 p.Rogers, R.E., 1994, Coalbed methane: principles and practice: Englewood Cliffs, NJ, Prentice Hall, 345 p.

Rohrbacher, T.J., D.D. Teeters, G.L. Sullivan, and L.M. Osmonson, 1993, Coal resource recoverability. A methodology: U.S. Bureau of Mines, Information Circular 9368, 48 p.Rohrbacher, T.J., J.A. Luppens, L.M. Osmonson, D.C. Scott, and P.A. Freeman, 2005, An external peer review of the U.S. Geological Survey energy resource program’s economically recoverable coal resource assessment methodology—report and comments: U.S. Geological Survey Open-File Report 2005-1076, 21 p.Rollins, M.S., A.D. Cohen, A.M. Bailey, and J.R. Durig, 1991, Organic chemical and petrography changes induced by early-stage artificial coalification of peats: Organic Geochemistry, v. 17, p. 451-465.Rollins, M.S., A.D. Cohen, and J.R. Durig, 1993, Effects of fires on the chemical and petrographic composition of peat in the Snuggedy Swamp, South Carolina: International Journal of Coal Geology, v. 22, p. 101-117.Romanak, K., R.S. Harmon, and Y. Kharaka, 2013, Geochemical aspects of geologic carbon storage: Applied Geochemistry, v. 30, p. 1-3.Romanov, V., and Y. Soong, 2009, Helium-volume dynamics of Upper Freeport coal powder and lumps: International Journal of Coal Geology, v. 77, p. 10-15.Romanov, V.N., A.L. Goodman, and J.W. Larsen, 2006, Errors in CO2 adsorption measurements caused by coal swelling: Energy and Fuels, v. 20, p. 415-416.Romanov, V.N., T.-B. Hur, J.J. Fazio, B.H. Howard, and G.A. Irdi, 2013, Comparison of high-pressure CO2 sorption isotherms on central Appalachian and San Juan Basin coals: International Journal of Coal Geology, v. 118, p. 89-94.Rono, N., R. Biagioni, C. Rovey II, and M. Gutiérrez, 2013, Geochemical sequestration reactions within the Lamotte Sandstone at five different locations in Missouri: Environmental Geosciences Journal, v. 20, no. 3.

Rose, C.D., 1991, Monitoring within-laboratory test variance: Journal of Coal Quality, v. 10, p. 43-48.Rosenbauer, R.J., B. Thomas, J.L. Bischoff, and J. Palandri, 2012, Carbon sequestration via reaction with basaltic rocks: Geochemical modeling and experimental results: Geochimica et Cosmochimica Acta, v. 89, p. 116-133. (igneous)Rosenberg, P., H.I. Petersen, and E. Thomsen, 1996, Combustion char morphology related to combustion temperature and coal petrography: Fuel, v. 75, p. 1071-1082.Ross, J.V., and R.M. Bustin, 1997, Vitrinite anisotropy resulting from simple shear experiments at high temperature and high confining pressure: International Journal of Coal Geology, v. 33, p. 153-168.Rost, F.W.D., 1991, Quantitative fluorescence microscopy: Cambridge University Press, 236 p.Rost, F.W.D., 1995, Fluorescence microscopy: Cambridge University Press, 710 p.Rothaemel, M., and H.-D. Holtmann, 2002, Methanol to propylene MTP—Lurgi’s way: Erdöl und Kohle-Erdgas-Petrochemie, v. 118, p. 234-237.

Rowan, E.L., M.B. Goldhaber, and J.R. Hatch, 2002, Regional fluid flow as a factor in the thermal history of the Illinois basin: constraints from fluid inclusions and the maturity of Pennsylvanian coals: AAPG Bulletin, v. 86, p. 257-277.Rowe, N.P., and T.P. Jones, 2000, Devonian charcoal: Palaeogeography, Palaeoclimatology, Palaeoecology, v. 164, p. 331-338.Rowley, D.B., A. Raymond, J.T. Parrish, A.L. Lottes, C.R. Scotese, and A.M. Ziegler, 1985, Carboniferous paleogeographic, phytogeographic, and paleoclimatic reconstructions: International Journal of Coal Geology, v. 5, p. 7-42.Roy, C., M. Hebert, and W. Kalkreuth, 1993, Vacuum pyrolysis of Canadian coals. Thermal decomposition characteristics of two high volatile bituminous coals: Erdol und Kohle-Erdgas-Petrochemie, v. 46, p. 66-73.Roy, J., P. Sarkar, S. Biswas, and A. Choudhury, 2009, Predictive equations for CO2 emission factors for coal combustion, their applicability in a thermal power plant and subsequent assessment of uncertainty in CO2 estimation: Fuel, v. 88, p. 792-798.Roy, M.M., 1965, Studies on coal macerals. III. Aerial oxidation of macerals: Economic Geology, v. 60, p. 1213-1217.

Rozak, A.T., and R.M. Bustin, 2001, Measuring permeability in coals utilizing well log data and LogFAC analysis: Tuscaloosa, Alabama, Proceedings, International Coalbed Methane Symposium, Paper 111, p. 121-131.Rozkosny, I., V. Machovic, H. Pavlikova, and B. Hemelikova, 1994, Chemical structure of migrabitumens from Silurian Crinoidea, Prague basin, Barrandian (Bohemia): Organic Geochemistry, v. 21, p. 1131-1140.Ruau, O., B. Pradier, P. Landais, and J.L. Gardette, 1996, Influence of the conditions of deposition on the chemistry and the reflectance variations of the Brent coals: Organic Geochemistry, v. 25, p. 325-339.Rubin, E.S., 2008, CO2 capture and transport: Elements, v. 4, p. 311-317.Ruble, T.E., 1990, Organic geochemical investigation of native bitumens from the Uinta Basin, Utah, U.S.A.: Norman, OK, University of Oklahoma, unpublished M.S. thesis, 155 p.Ruble, T.E., A.J. Bakel, and R.P. Philp, 1994, Compound specific isotopic variability in Uinta basin native bitumens: paleoenvironmental implications: Organic Geochemistry, v. 21, p. 661-671.Ruble, T.E., and R.P. Philp, 1991, Geochemical investigation of native bitumens from the Uinta basin, Utah, U.S.A.: The Compass, v. 68, p. 135-150.Ruble, T.E., and R.P. Philp, 1992, A reevaluation of the geochemical characteristics of solid bitumens from the Ouachita Mountains, Oklahoma: Oklahoma Geological Survey, Circular 93, p. 337-342.

Rogers, M.A., 1980, Application of organic facies concepts to hydrocarbon source rock evaluation, in D.H. Welte, chairman, Origin, migration and accumulation of hydrocarbons: Proceedings, Tenth World Petroleum Congress, v. 2: Philadelphia, Heyden & Son Inc., p. 23-30.

Rogers, R.S.C., and L.G. Austin, 1989, Coal-size reduction, in R. Klein and R. Wellek, eds., Sample selection, aging, and reactivity of coal: New York, John Wiley & Sons, p. 103-153. (combustion p. 143-146)

Rose, A., T. Torries, and W. Labys, 1991, Clean coal technologies and future prospects for coal, in J.M. Hollander, ed., Annual Review of Energy and the Environment: Palo Alto, Annual Reviews Inc., Energy and the Environment, v. 16, p. 59-90.

Rouzaud, J.N., and A. Oberlin, 1984, Contribution of high resolution electron microscopy (TEM) to organic materials characterization and interpretation of their reflectance, in B. Durand, ed., Thermal phenomena in sedimentary basins: Paris, Editions Technip, p. 127-134.Rouzaud, J.-N., and A. Oberlin, 1990, The characterization of coals and cokes by transmission electron microscopy, in H. Charcosset, ed., Advanced methodologies in coal characterization: Elsevier, p. 311-355.

Royer, D.L., R.A. Berner, I.P. Montañez, N.J. Tabor, and D.J. Beerling, 2004, CO2 as a primary driver of Phanerozoic climate: GSA Today, v. 14, no. 3, p. 4-10.

Ruble, T.E., and R.P. Philp, 1994, Uinta basin wurtzilite: a product of natural vulcanization?: Organic Geochemistry, v. 22, p. 127-136.Ruble, T.E., M.D. Lewan, and B.J. Cardott, 1999, Uinta basin solid hydrocarbons: new data and new insights: TSOP Newsletter, v. 16, no. 3, p. 13-16.

Rui, L., and G.P. Ritz, 1993, Studying individual maceral using i.r. microspectroscopy and implication on oil versus gas/condensate proneness and "low-rank" generation: Organic Geochemistry, v. 20, p. 695-706.Ruilin, Z., and I.S. Lowndes, 2010, The application of a coupled artificial neural network and fault tree analysis model to predict coal and gas outbursts: International Journal of Coal Geology, v. 84, p. 141-152.Ruppel, T.C., and T.A. Sarkus, 1998, Unburned carbon on fly ash: a burning issue for coal-fired utilities: Energeia, v. 9, no. 1, p. 5-6.Ruppel, T.C., C.T. Grein, and D. Bienstock, 1972, Adsorption of methane/ethane mixtures on dry coal at elevated pressures: Fuel, v. 51, p. 297-303.Ruppert, L., R. Finkelman, E. Boti, M. Milosavljevic, S. Tewalt, N. Simon, and F. Dulong, 1996, Origin and significance of high nickel and chromium concentrations in Pliocene lignite of the Kosovo Basin, Serbia: International Journal of Coal Geology, v. 29, p. 235-258.Ruppert, L.F., C.B. Cecil, R.W. Stanton, and R.P Christian, 1985, Authigenic quartz in the Upper Freeport coal bed, west-central Pennsylvania: Journal of Sedimentary Petrology, v. 55, p. 334-339.Ruppert, L.F., J.A. Minkin, J.J. McGee, and C.B. Cecil, 1992, An unusual occurrence of arsenic-bearing pyrite in the Upper Freeport coal bed, west-central Pennsylvania: Energy & Fuels, v. 6, p. 120-125.Ruppert, L.F., J.C. Hower, and C.F. Eble, 2005, Arsenic-bearing pyrite and marcasite in the Fire Clay coal bed, Middle Pennsylvanian Breathitt Formation, eastern Kentucky: International Journal of Coal Geology, v. 63, p. 27-35.Ruppert, L.F., J.C. Hower, and C.F. Eble, 2005, Arsenic-bearing pyrite and marcasite in the Fire Clay coal bed, Middle Pennsylvanian Breathitt Formation, eastern Kentucky: International Journal of Coal Geology, v. 63, p. 27-35.Ruppert, L.F., J.C. Hower, R.T. Ryder, J.R. Levine, M.H. Trippi, and W.C. Grady, 2010, Geologic controls on thermal maturity patterns in Pennsylvanian coal-bearing rocks in the Appalachian Basin: International Journal of Coal Geology, v. 81, p. 169-181.

Ruppert, L.F., S.J. Tewalt, L.J. Bragg, and R.N. Wallack, 1999, A digital resource model of the Upper Pennsylvanian Pittsburgh coal bed, Monongahela Group, northern Appalachian basin coal region, USA: International Journal of Coal Geology, v. 41, p. 3-24.Russell, P.L., 1980, History of western oil shale: East Brunswick, N.J., The Center for Professional Advancement, 152 p.Russell, P.L., 1990, Oil shales of the world, their origin, occurrence and exploitation: New York, Pergamon Press, 753 p.

Ruthven, C.L., 2004, Reducing global warming by storing carbon dioxide beneath the Earth’s surface—exploring the prospects for carbon sequestration: Kentucky Geology, v. 5, no. 1.Ryan, B., 1992, Estimation of coal washability using small samples: Journal of Coal Quality, v. 11, nos. 1-2, p. 13-19.Ryan, B., 2003, Overview of the coalbed methane potential of Tertiary coal basins in the interior of British Columbia: British Columbia Ministry of Energy and Mines, Geological Fieldwork 2002, Paper 2003-1, p. 1-23.Ryan, B.D., 2002, Note on desorption results of Comox Formation coals, Courtenay area, Vancouver Island, British Columbia: Geological Fieldwork 2001: B.C. Ministry of Energy and Mines, Paper 2002-1, p. 319-330.Ryan, B.D., 2003, Pseudovitrinite: possible implications for gas saturation in coals and surrounding rocks: Geological Fieldwork 2002: B.C. Ministry of Energy and Mines, Paper 2003-1, p. 203-212.

Ryder, R.T., P.C. Hackley, H. Alimi, and M.H. Trippi, 2013, Evaluation of thermal maturity in the low maturity Devonian shales of the northern Appalachian Basin: AAPG Search and Discovery Article 10477, 228 p.Ryder, R.T., P.C. Hackley, H. Alimi, and M.H. Trippi, 2013, Evaluation of thermal maturity in the low maturity Devonian shales of the northern Appalachian Basin: AAPG Search and Discovery Article 10477, 228 p.Ryer, T.A., 1981, Deltaic coals of Ferron Sandstone member of Mancos Shale: predictive model for Cretaceous coal-bearing strata of Western Interior: AAPG Bulletin, v. 65, p. 2323-2340.Ryer, T.A., and A.W. Langer, 1980, Thickness change involved in the peat-to-coal transformation for a bituminous coal of Cretaceous age in central Utah: Journal of Sedimentary Petrology, v. 50, p. 987-992.Sabel, M., A. Bechtel, W. Püttmann, and S. Hoernes, 2005, Palaeoenvironment of the Eocene Eckfeld Maar lake (Germany): implications from geochemical analysis of the oil shale sequence: Organic Geochemistry, v. 36, p. 873-891.Sachsenhofer, R.F., 2004, A short report of the investigations made on the facies of Austrian coal deposits: International Journal of Coal Geology, v. 58, p. 87-89.Sachsenhofer, R.F., V.A. Privalov, and E.A. Panova, 2012, Basin evolution and coal geology of the Donets Basin (Ukraine, Russia): An overview: International Journal of Coal Geology, v. 89, p. 26-40.

Saghafi, A., 2010, Potential for ECBM and CO2 storage in mixed gas Australian coals: International Journal of Coal Geology, v. 82, p. 240-251.Saghafi, A., 2010, Potential for ECBM and CO2 storage in mixed gas Australian coals: International Journal of Coal Geology, v. 82, p. 240-251.Saghafi, A., 2012, A Tier 3 method to estimate fugitive gas emissions from surface coal mining: International Journal of Coal Geology, v. 100, p. 14-25.Saghafi, A., K.L. Pinetown, P.G. Grobler, and J.H.P. van Heerden, 2008, CO2 storage potential of South African coals and gas entrapment enhancement due to igneous intrusions: International Journal of Coal Geology, v. 73, p. 74-87.Saghafi, A., K.L. Pinetown, P.G. Grobler, and J.H.P. van Heerden, 2008, CO2 storage potential of South African coals and gas entrapment enhancement due to igneous intrusions: International Journal of Coal Geology, v. 73, p. 74-87.Saghafi, A., M. Faiz, and D. Roberts, 2007, CO2 storage and gas diffusivity properties of coals from Sydney Basin, Australia: International Journal of Coal Geology, v. 70, p. 240-254.

Ruch, R.R., H.J. Gluskoter, and E.J. Kennedy, 1971, Mercury content of Illinois coals: Illinois State Geological Survey, Environmental Geology Notes 43, 15 p. http://library.isgs.uiuc.edu/Pubs/pdfs/egs/eg043.pdf Rühl, W., 1982, Tar (extra heavy oil) sands and oil shales, in H. Beckmann, ed., Geology of petroleum: Stuttgart, Ferdinand Enke Publishers, v. 6, 149 p.

Ruppert, L.F., S.G. Neuzil, C.B. Cecil, and J.S. Kane, 1993, Inorganic constituents from samples of a domed and lacustrine peat, Sumatra, Indonesia, in J.C. Cobb and C.B. Cecil, eds., Modern and ancient coal-forming environments: GSA Special Paper 286, p. 83-96.

Russell, S.J., and S.M. Rimmer, 1979, Analysis of mineral matter in coal, coal gasification ash, and coal liquefaction residues by Scanning Electron Microscopy and X-ray diffraction, in C. Karr, Jr., ed., Analytical methods for coal and coal production, v. 3: New York, Academic Press, p. 133-162.Russell, S.J., and S.M. Rimmer, 1979, Analysis of mineral matter in coal, coal gasification ash, and coal liquefaction residues by scanning electron microscopy and x-ray diffraction, in C. Karr, Jr., ed., Analytical methods for coal and coal products, v. 3: New York, Academic Press, p. 133-162.

Rychlicki, S., K. Twardowski, J. Kwarcinski, and M. Karwasiecka, 1997, Analysis of inaccuracy of methane content evaluations in the Upper Silesian coal basin, in M. Podemski, S. Dybova-Jachowicz, K. Jaworowski, J. Jureczka, and R. Wagner, eds., Proceedings of the XIII International Congress on the Carboniferous and Permian: Warsaw, Polish Geological Institute, Prace, v. 157, pt. 2, p. 387-394.

Saether, O.M., 2004, Oil shale—an alternative energy resource?: Geological Survey of Norway, GEO ExPro, v. 1, no. 3, p. 26-32. (http://aviser.imaker.no/data/f/0/18/72/4_5301_0/GeoExpro_26-32.pdf) Saether, O.M., D. Banks, U. Kirso, L. Bityukova, and J.E. Sorlie, 2004, The chemistry and mineralogy of waste from retorting and combustion of oil shale, in R. Gieré and P. Stille, eds., Energy, waste, and the environment: a geochemical perspective: London, Geological Society, Special Publication 236, p. 263-284.

Saghafi, A., M. Faiz, and D. Roberts, 2007, CO2 storage and gas diffusivity properties of coals from Sydney Basin, Australia: International Journal of Coal Geology, v. 70, p. 240-254.Sahay, V.K., 2011, Effect of concentration of dispersed organic matter on optical maturity parameters. Interlaboratory results of the organic matter concentration working group of the ICCP: Discussion: International Journal of Coal Geology, v. 85, p. 184-185.Sahu, H.B., S.S. Mahapatra, and D.C. Panigrahi, 2009, An empirical approach for classification of coal seams with respect to the spontaneous heating susceptibility of Indian coals: International Journal of Coal Geology, v. 80, p. 175-180. (coal mine fire)Saikia, B.K., C.R. Ward, M.L.S. Oliveira, J.C. Hower, B.P. Baruah, M. Braga, and L.F. Silva, 2014, Geochemistry and nano-mineralogy of two medium-sulfur northeast Indian coals: International Journal of Coal Geology, v. 121, p. 26-34.Saikia, K., and B.C. Sarkar, 2013, Coal exploration modeling using geostatistics in Jharia coalfield, India: International Journal of Coal Geology, v. 112, p. 36-52.Sajwan, K.S., A.K. Alva, and R.F. Keefer, eds., 1999, Biogeochemistry of trace elements in coal and coal combustion byproducts: New York, Kluwer Academic/Plenum Publishers, 359 p.Sajwan, K.S., A.K. Alva, and R.F. Keefer, eds., 1999, Biogeochemistry of trace elements in coal and coal combustion byproducts: New York, Kluwer Academic/Plenum Publishers, 359 p.Sakulpitakphon, T., J.C. Hower, A.S. Trimble, W.H. Schram, and G.A. Thomas, 2000, Mercury capture by fly ash: study of the combustion of a high-mercury coal at a utility boiler: Energy & Fuels, v. 14, p. 727-733.Sakulpitakphon, T., J.C. Hower, A.S. Trimble, W.H. Schram, and G.A. Thomas, 2003, Arsenic and mercury partitioning in fly ash at a Kentucky power plant: Energy & Fuels, v. 17, p. 1028-1033.Sakulpitakphon, T., J.C. Hower, and D.N. Taulbee, 2003, Predicted CO2 emissions from maceral concentrates of high volatile bituminous Kentucky and Illinois coals: International Journal of Coal Geology, v. 54, p. 185-192.Sakulpitakphon, T., J.C. Hower, and D.N. Taulbee, 2003, Predicted CO2 emissions from maceral concentrates of high volatile bituminous Kentucky and Illinois coals: International Journal of Coal Geology, v. 54, p. 185-192.Sakulpitakphon, T., J.C. Hower, W.H. Schram, and C. R. Ward, 2004, Tracking mercury from the mine to the power plant: geochemistry of the Manchester coal bed, Clay County, Kentucky: International Journal of Coal Geology, v. 57, p. 127-141.Sakulpitakphon, T., J.C. Hower, W.H. Schram, and C.R. Ward, 2004, Tracking mercury from the mine to the power plant: geochemistry of the Manchester coal bed, Clay County, Kentucky: International Journal of Coal Geology, v. 57, p. 127-141.Sakurovs, R., 2003, Interactions between coking coals in blends: Fuel, v. 82, p. 439-450.Sakurovs, R., 2012, Relationships between CO2 sorption capacity by coals as measured at low and high pressure and their swelling: International Journal of Coal Geology, v. 90-91, p. 156-161.Sakurovs, R., and S. Lavrencic, 2011, Contact angles in CO2-water-coal systems at elevated pressures: International Journal of Coal Geology, v. 87, p. 26-32.Sakurovs, R., D. French, and M. Grigore, 2007, Quantification of mineral matter in commercial cokes and their parent coals: International Journal of Coal Geology, v. 72, p. 81-88.Sakurovs, R., D. French, and M. Grigore, 2007, Quantification of mineral matter in commercial cokes and their parent coals: International Journal of Coal Geology, v. 72, p. 81-88.Sakurovs, R., D. French, and M. Grigore, 2012, Effect of the NSC reactivity test on coke mineralogy: International Journal of Coal Geology, v. 94, p. 201-205.Sakurovs, R., D. French, and M. Grigore, 2012, Effect of the NSC reactivity test on coke mineralogy: International Journal of Coal Geology, v. 94, p. 201-205.Sakurovs, R., L. He, Y.B. Melnichenko, A.P. Radlinski, T. Blach, H. Lemmel, and D.F.R. Mildner, 2012, Pore size distribution and accessible pore size distribution in bituminous coals: International Journal of Coal Geology, v. 100, p. 51-64.

Sakurovs, R., S. Day, and S. Weir, 2009, Causes and consequences of errors in determining sorption capacity of coals for carbon dioxide at high pressure: International Journal of Coal Geology, v. 77, p. 16-22.Sakurovs, R., S. Day, S. Weir, and G. Duffy, 2008, Temperature dependence of sorption gases by coals and charcoals: International Journal of Coal Geology, v. 73, p. 250-258.Sakurovs, R., S. Day, S. Weir, and G. Duffy, 2008, Temperature dependence of sorption gases by coals and charcoals: International Journal of Coal Geology, v. 73, p. 250-258.Sakurovs, R., S. Weir, D. French, and S. Day, 2011, Effect of impurity gases in carbon dioxide on sorption behavior and mineral matter in an Australian bituminous coal: International Journal of Coal Geology, v. 86, p. 367-371.Sakurovs, R., S. Weir, D. French, and S. Day, 2011, Effect of impurity gases in carbon dioxide on sorption behavior and mineral matter in an Australian bituminous coal: International Journal of Coal Geology, v. 86, p. 367-371. (SO2 reduced CO2 sorption capacity)Salazar, J., D.A. McVay, and W.J. Lee, 2010, Development of an improved methodology to assess potential unconventional gas resources: Natural Resources Research, v. 19, p. 253-268.Salehi, I.A., and S. Gowelly, 2005, Seismic imaging for site selection and monitoring of carbon dioxide sequestration, part 1—field studies: GasTIPS, v. 11, no. 4, p. 3-7.Salehi, I.A., S. Gowelly, and S. Batarseh, 2006, Seismic imaging for site selection and monitoring of carbon dioxide sequestration, part 2—laboratory studies: GasTIPS, v. 12, no. 1, p. 2-4.Salmachi, A., M. Sayyafzadeh, and M. Haghighi, 2013, Infill well placement optimization in coal bed methane reservoirs using genetic algorithm: Fuel, v. 111, p. 248-258.Salmon, V., S. Derenne, E. Lallier-Vergès, C. Largeau, and B. Beaudoin, 2000, Protection of organic matter by mineral matrix in a Cenomanian black shale: Organic Geochemistry, v. 31, p. 463-474.Salmon, V., S. Derenne, E. Lallier-Vergès, C. Largeau, and B. Beaudoin, 2000, Protection of organic matter by mineral matrix in a Cenomanian black shale: Organic Geochemistry, v. 31, p. 463-474.

Samanta, U., C.S. Mishra, and K.N. Misra, 1994, Indian high wax crude oils and the depositional environments of their source rocks: Marine and Petroleum Geology, v. 11, p. 756-759.Sams, J.I., G. Veloski, B.D. Smith, B.J. Minsley, M.A. Engle, B.A. Lipinski, R. Hammack, and J.W. Zupancic, 2014, Application of near-surface geophysics as part of a hydrologic study of a subsurface drip irrigation system along the Powder River floodplain near Arvada, Wyoming: International Journal of Coal Geology, v. 126, p. 128-139.Sander, P.M., and C.T. Gee, 1990, Fossil charcoal: techniques and applications: Review of Palaeobotany and Palynology, v. 63, p. 269-279.Sanderson, G.A., and L.W. Berggren, 1998, White paper: update on application of §29 tax credit to coal seam gas: U.S. Environmental Protection Agency, 16 p.Sandison, C.M., R. Alexander, R.I. Kagi, and C.J. Boreham, 2002, Sulfurisation of lipids in a marine-influenced lignite: Organic Geochemistry, v. 33, p. 1053-1077.

Sakurovs, R., L.J. Lynch, and W.A. Barton, 1991, Molecular conformation and stability of coal macerals, in H.H. Schobert, K.D. Bartle, L.J. Lynch, and P.H. Given, eds., Coal science II: Washington, D.C., American Chemical Society Symposium Series 461, p. 111-126.

Salvador, A., 2005, Coalbed methane, in Energy: A historical perspective and 21st century forecast: AAPG Studies in Geology 54, p. 68-72.Salvador, A., 2005, Oil shales, in Energy: a historical perspective and 21st century forecast: AAPG Studies in Geology 54, p. 89-94.

Sandvik, E.I., W.A. Young, and D.J. Curry, 1992, Expulsion from hydrocarbon sources: the role of organic absorption, in C.B. Eckardt, J.R. Maxwell, S.R. Larter, and D.A.C. Manning, eds., Advances in organic geochemistry 1991, part I. Advances and applications in energy and the natural environment: Organic Geochemistry, v. 19, p. 77-87.

Sanei, H., F. Goodarzi, and P.M. Outridge, 2010, Spatial distribution of mercury and other trace elements in recent lake sediments from central Alberta, Canada: an assessment of the regional impact of coal-fired power plants: International Journal of Coal Geology, v. 82, p. 105-115.Sanei, H., F. Goodarzi, and P.M. Outridge, 2010, Spatial distribution of mercury and other trace elements in recent lake sediments from central Alberta, Canada: an assessment of the regional impact of coal-fired power plants: International Journal of Coal Geology, v. 82, p. 105-115.Sanfilipo, J.R., P.D. Warwick, C.E. Barker, L.R.H. Biewick, and R.W. Stanton, 2000, A show of methane from shallow low-rank coal in the Gulf Coast of Texas, and its implications for basin-wide commercial potential (abstract): TSOP Abstracts and Program, v. 17, p. 77-78.Sang, S., H. Xu, L. Fang, G. Li, and H. Huang, 2010, Stress relief coalbed methane drainage by surface vertical wells in China: International Journal of Coal Geology, v. 82, p. 196-203.Sanner, W.S., and D.C. Benson, 1979, Demonstrated reserve base of U.S. coals with potential for use in the manufacture of metallurgical coke: U.S. Bureau of Mines, Information Circular 8805, 154 p.Santarosa, C.S., D. Crandall, I.V. Haljasmaa, T.-B. Hur, J.J. Fazio, R.P. Warzinski, R. Heemann, J.M.M. Ketzer, and V.N. Romanov, 2013, CO2 sequestration otential of Charqueadas coal field in Brazil: International Journal of Coal Geology, v. 106, p. 25-34.Sanyal, A., 1983, The role of coal macerals in combustion: Journal of the Institute of Energy, v. 56, p. 92-95.Sarana, S., and R. Kar, 2011, Effect of igneous intrusive on coal microconstituents: Study from an Indian Gondwana coalfield: International Journal of Coal Geology, v. 85, p. 161-167.Saranchuk, W.I., T.G. Shendrik, V. Simonova, J.L. Komraus, and E.S. Poliel, 1994, Hydrogenation of Ukrainian saline coals. Iron compounds and their transformation during hydrogenation: Erdöl und Kohle-Erdgas-Petrochemie, v. 47, p. 385-388.Sarkus, T.A., 2008, Fossil energy, clean coal technology, and FutureGen: Coal Age, v. 113, no. 7, p. 56-59.

Sassen, R., 1988, Geochemical and carbon isotopic studies of crude oil destruction, bitumen precipitation, and sulfate reduction in the deep Smackover Formation: Organic Geochemistry, v. 12, p. 351-361.Sassen, R., C.H. Moore, J.A. Nunn, F.C. Meendsen, and E. Heydari, 1987, Geochemical studies of crude oil generation, migration, and destruction in the Mississippi salt basin: Transactions Gulf Coast Association of Geological Societies, v. 37, p. 217-224.Sassen, R., H.H. Roberts, R. Carney, A.V. Milkov, D.A. DeFreitas, B. Lanoil, and C. Zhang, 2004, Free hydrocarbon gas, gas hydrate, and authigenic minerals in chemosynthetic communities of the northern Gulf of Mexico continental slope: relation to microbial processes: Chemical Geology, v. 205, p. 195-217.Sassen, R., P. Grayson, G. Cole, H.H. Roberts, and P. Aharon, 1991, Hydrocarbon seepage and salt-dome related carbonate reservoir rocks of the U.S. Gulf Coast: Transactions Gulf Coast Association of Geological Societies, v. 41, p. 570-578.

Sato, T., 1981, Methane recovery from coalbeds: surface and physical properties of western United States coals: Albuquerque, University of New Mexico, unpublished M.S. thesis, 78 p.Saulsberry, J.L., P.S. Schafer, and R.A. Schraufnagel, eds., 1996, A guide to coalbed methane reservoir engineering: Chicago, Gas Research Institute, variously pagenated.

Saulsberry, J.L., S.D. Spafford, P.F. Steidl, L.A. Litzinger, A.H. Durden, C.L. Rochester, V.A. Kuuskraa, and G.B.C. Young, 1994, Effective completions for shallow coal seams: Gas Research Institute, Topical Report, GRI-93/0366, 77 p.Saunders, J.T., B.M.C. Tsai, and R.T. Yang, 1985, Adsorption of gases on coals and heat-treated coals at elevated temperatures and pressure: 2. Adsorption from hydrogen-methane mixtures: Fuel, v. 64, p. 621-626.Savage, H.K., 1967, The rock that burns: Boulder, CO, Pruett Press, 111 p.Savinskii, I.D., 1965, Probability tables for locating elliptical underground masses with a rectangular grid (English translation): New York, Consultants Bureau, 110 p.Sawada, K., H. Nakamura, T. Arai, and M. Tsukagoshi, 2013, Evaluation of paleoenvironment using terpenoid biomarkers in lignites and plant fossil from the Miocene Tokiguchi Porcelain Clay Formation at the Onada mine, Tajimi, central Japan: International Journal of Coal Geology, v. 107, p. 78-89.Sawin, R.S., and L.L. Brady, 2001, Natural gas from coal in eastern Kansas: Kansas Geological Survey, Public Information Circular 19, 4 p.Saxby, J., and M. Shibaoka, 1986, Coal and coal macerals as source rocks for oil and gas: Applied Geochemistry, v. 1, p. 25-36.Saxby, J.D., 1970, Isolation of kerogen in sediments by chemical methods: Chemical Geology, v. 6, p. 173-184.Saxby, J.D., 1980, Atomic H/C ratios and the generation of oil from coals and kerogens: Fuel, v. 59, p. 305-307.Saxby, J.D., A.R.J. Bennett, J.F. Corcoran, D.E. Lambert, and K.W. Riley, 1986, Petroleum generation: simulation over 10 years of hydrocarbon formation from Torbanite and brown coal in a subsiding basin: Organic Geochemistry, v. 9, p. 69-81.Saxby, J.D., and M. Shibaoka, 1986, Coal and coal macerals as source rocks for oil and gas: Applied Geochemistry, v. 1, p. 25-36.Saxena, R., G.K.B. Navale, D. Chandra, and Y.V.S. Prasad, 1989, Spontaneous combustion of some Permian coal seams of India: an explanation based on microscopic and physico-chemical properties: The Palaeobotanist, v. 38, p. 58-82.Sayers, A.C., C.M. Boyer, II, T.J. Frenzel, and R.A. Rodgers, 2004, Technologies key deep CBM success: American Oil & Gas Reporter, v. 47, no. 3, p. 79, 81-85.Schapiro, N., and R.J. Gray, 1964, The use of coal petrography in coke-making: Fuel, v. 11, p. 234-242.Schapiro, N., R.J. Gray, and G.R. Eusner, 1961, Recent developments in coal petrography: Blast Furnace, Coke Oven, and Raw Material Conference, American Institute of Mining, Metallurgical, and Petroleum Engineers, v. 20, p. 89-109.Schatzel, S.J., and B.W. Stewart, 2003, Rare earth element sources and modifications in the Lower Kittanning coal bed, Pennsylvania: implications for the origin of coal mineral matter and rare earth element exposure in underground mines: International Journal of Coal Geology, v. 54, p. 223-251.Schatzel, S.J., and B.W. Stewart, 2012, A provenance study of mineral matter in coal from Appalachian Basin coal mining regions and implications regarding the respirable health of underground coal workers: A geochemical and Nd isotope investigation: International Journal of Coal Geology, v. 94, p. 123-136.Schatzel, S.J., and B.W. Stewart, 2012, A provenance study of mineral matter in coal from Appalachian Basin coal mining regions and implications regarding the respirable health of underground coal workers: A geochemical and Nd isotope investigation: International Journal of Coal Geology, v. 94, p. 123-136.Scheckler, S.E., 1986, Geology, floristics and paleoecology of Late Devonian coal swamps from Appalachian Laurentia (U.S.A.): Annales de la Société Géologique de Belgique, v. 109, p. 209-222.Scheidt, G., and R. Littke, 1989, Comparative organic petrology of interlayered sandstones, siltstones, mudstones and coals in the Upper Carboniferous Ruhr basin, northwest Germany, and their thermal history and methane generation: Geologische Rundshau, v. 78, p. 375-390.Scheidt, G., and R. Littke, 1989, Comparative organic petrology of interlayered sandstones, siltstones, mudstones and coals in the Upper Carboniferous Ruhr basin, northwest Germany, and their thermal history and methane generation: Geologische Rundshau, v. 78, p. 375-390.

Sasaki, E., 2014, Toyokawa field yields oil, prehistoric asphalt: AAPG Explorer, v. 35, no. 10, p. 46, 48, 50. http://www.aapg.org/publications/news/explorer/column/articleid/12431/toyokawa-field-yields-oil-prehistoric-asphalt

Sasson, R., 1981, Increased vitrinite reflectance associated with uranium mineralization, in M. Bjorøy et al., eds., Advances in organic geochemistry 1981: New York, John Wiley & Sons, p. 94-98.

Saulsberry, J.L., R.A. Schraufnagel, and A.H. Jones, 1992, Fracture height growth and production from multiple reservoirs, in Coalbed methane: Society of Petroleum Engineers, Reprint Series 35, p. 197-207.

Schenk, C.J., R.M. Pollastro, and R.J. Hill, 2006, Natural bitumen resources of the United States: U.S. Geological Survey Fact Sheet 2006-3133, 2 p. http://pubs.usgs.gov/fs/2006/3133/

Schimmelmann, A., M. Mastalerz, L. Gao, P.E. Sauer, and K. Topalov, 2009, Dike intrusions into bituminous coal, Illinois Basin: H, C, N, O isotopic responses to rapid and brief heating: Geochimica et Cosmochimica Acta, v. 73, p. 6264-6281.

Schmidt, L.D., and J.L. Elder, 1940, Atmospheric oxidation of coal at moderate temperatures: Industrial and Engineering Chemistry, v. 32, p. 249-256.

Schnitzer, M., and S.I.M. Skinner, 1974, The low temperature oxidation of humic substances: Canadian Journal of Chemistry, v. 52, p. 1072-1080.Schobert, H.H., 1987, Coal — the energy source of the past and future: Washington, D.C., American Chemical Society.Schobert, H.H., K.D. Bartle, and L.J. Lynch, eds., 1991, Coal science II: Washington, D.C., American Chemical Society Symposium Series 461, 337 p.Schobert, H.H., K.D. Bartle, L.J. Lynch, and P.H. Given, 1991, Coal science II: Washington, D.C., American Chemical Society Symposium Series 461, 337 p.Schoenherr, J., R. Littke, J.L. Urai, P.A. Kukla, and Z. Rawahi, 2007, Polyphase thermal evolution in the Infra-Cambrian Ara Group (South Oman Salt Basin) as deduced by maturity of solid reservoir bitumen: Organic Geochemistry, v. 38, p. 1293-1318.Schoenherr, J., R. Littke, J.L. Urai, P.A. Kukla, and Z. Rawahi, 2007, Polyphase thermal evolution in the Infra-Cambrian Ara Group (South Oman Salt Basin) as deduced by maturity of solid reservoir bitumen: Organic Geochemistry, v. 38, p. 1293-1318.

Schon, S.C., and A.A. Small, III, 2006, Climate change and the potential of coal gasification: Geotimes, v. 51, no. 9, p. 20-23.Schopf, J,M., 1960, Field description and sampling of coal beds: U.S. Geological Survey Bulletin 1111-B, 67 p.Schopf, J.M., 1939, Coal balls as an index to the constitution of coal: Transactions Illinois State Academy of Science, v. 31, p. 187-189.Schopf, J.M., 1939, Coal balls as an index to the constitution of coal: Transactions of the Illinois State Academy of Science, v. 31, p. 187-189.Schopf, J.M., 1947, Botanical aspects of coal petrology: coal from the Coos Bay field in southwestern Oregon: American Journal of Botany, v. 34, p. 335-354.Schopf, J.M., 1948, Variable coalification: the processes involved in coal formation: Economic Geology, v. 43, p. 207-225.Schopf, J.M., 1949, Cannel, boghead, torbanite, oil shale: Economic Geology, v. 44, p. 68-71.Schopf, J.M., 1952, Was decay important in origin of coal?: Journal of Sedimentary Petrology, v. 22, p. 61-69.Schopf, J.M., 1956, A definition of coal: Economic Geology, v. 51, p. 521-527.Schopf, J.M., 1960, Field description and sampling of coal beds: U.S. Geological Survey Bulletin 1111-B, 67 p.Schopf, J.M., 1960, Field description and sampling of coal beds: U.S. Geological Survey Bulletin 1111-B, 67 p.Schopf, J.M., 1962, A preliminary report on plant remains and coal of the sedimentary section in the central range of the Horlick Mountains, Antarctica: The Ohio State University, Institute of Polar Studies, Research Foundation Report 2 (Project 1132), 61 p.Schopf, J.M., 1966, Definitions of peat and coal and of graphite that terminates the coal series (graphocite): Journal of Geology, v. 74, p. 584-592.Schopf, J.M., 1971, Comment about the origin of micrinite: Economic Geology, v. 66, p. 1153-1156.

Schopf, J.M., 1975, Modes of fossil preservation: Review of Palaeobotany and Palynology, v. 20, p. 27-53.Schopf, J.M., 1975, Modes of fossil preservation: Review of Palaeobotany and Palynology, v. 20, p. 27-53.

Schopf, J.M., 1978, Further suggestions about coal description in the field: American Society for Testing and Materials Special Technical Publication 661, p. 3-8.Schopf, J.M.., 1960, Field description and sampling of coal beds: U.S. Geological Survey Circular 1111-B, p. 25-70.

Schubotz, F., J.S. Lipp, M. Elvert, S. Kasten, X. Prieto Mollar, M. Zabel, G. Bohrmann, and K.-U. Hinrichs, 2011, Petroleum degradation and associated microbial signatures at the Chapopote asphalt volcano, southern Gulf of Mexico: Geochimica et Cosmochimica Acta, v. 75, p. 4377-4398.

Schenk, C.J., V.F. Nuccio, R.M. Flores, R.C. Johnson, S.B. Roberts, T.M. Finn, and J. Ridgley, 2003, Coal-bed gas resources of the Rocky Mountain region: U.S. Geological Survey Fact Sheet FS 0158-02, 2 p. http://pubs.usgs.gov/fs/fs-158-02/

Schlatter, L.E., 1969, Deposition, formation, and classification of oil shale, in Selected papers U.N. oil-shale symposium: Cameron and Jones, Inc., v. 2, p. 44-49.Schmal, D., 1989, Spontaneous heating of stored coal, in C.R. Nelson, ed., Chemistry of coal weathering: New York, Elsevier Science Publishers, Coal Science and Technology, v. 14, p. 133-213.Schmidt, L.D., 1945, Changes in coal during storage, in H.H. Lowry, ed., Chemistry of coal utilization, v. 1: New York, John Wiley & Sons, p. 627-676.

Schmidt, M.W.I., H. Knicker, P.G. Hatcher, and I. Kögel-Knabner, 1997, Does ultrasonic dispersion and homogenization by ball milling change the chemical structure of organic matter in geochemical samples? — a CPMAS 13C NMR study with lignin: Organic Geochemistry, v. 26, p. 491-496.

Scholes, P.L., and D. Johnston, 1993, Coalbed methane applications of wireline logs, in B.E. Law and D.D. Rice, eds., Hydrocarbons from coal: AAPG Studies in Geology 38, p. 287-302.Scholes, P.L., and D. Johnston, 1993, Coalbed methane applications of wireline logs, in B.E. Law and D.D. Rice, eds., Hydrocarbons from coal: AAPG Studies in Geology 38, p. 287-302.

Schopf, J.M., 1973, Coal, climate and global tectonics, in D.H. Tarling and S.K. Runcorn, eds., Implications of continental drift to the earth sciences, v. 1: London, Academic Press, p. 609-622.

Schopf, J.M., 1975, Pennsylvanian climate in the United States, in E.D. McKee, E.J. Crosby, and others, Paleotectonic investigations of the Pennsylvanian System in the United States: U.S. Geological Survey Professional Paper 853, part II, p. 23-31.Schopf, J.M., 1978, Further suggestions about coal description in the field, , in R.R. Dutcher, ed., Field description of coal: Philadelphia, PA, American Society for Testing and Materials, Special Technical Publication 661, p. 3-8.

Schraufnagel, R.A., 1992, Multiple seam completion and production experience at Rock Creek, in Coalbed methane: Society of Petroleum Engineers, Reprint Series 35, p. 120-130.Schraufnagel, R.A., 1993, Coalbed methane production, in B.E. Law and D.D. Rice, eds., Hydrocarbons from coal: AAPG Studies in Geology 38, p. 341-359.Schroeder, K., and E. Ozdemir, 2001, Sequestration of carbon dioxide in coal seams: National Energy Technology Laboratory First National Conference on Carbon Sequestration, 10 p. http://www.netl.doe.gov/publications/proceedings/01/carbon_seq/3a4.pdfSchroeder, K., E. Ozdemir, and B.I. Morsi, 2001, Sequestration of carbon dioxide in coal seams: National Energy Technology Laboratory, First National Conference on Carbon Sequestration, 10 p. http://www.netl.doe.gov/publications/proceedings/01/carbon_seq/3a4.pdf

Schutter, S.R., and P.H. Heckel, 1985, Missourian (early Late Pennsylvanian) climate in Midcontinent North America: International Journal of Coal Geology, v. 5, p. 111-140.Schwarzbauer, J., R. Littke, R. Meier, and H. Strauss, 2013, Stable carbon isotope ratios of aliphatic biomarkers in Late Palaeozoic coals: International Journal of Coal Geology, v. 107, p. 127-140.

Schwochow, S.D., 2006, Coalbed gas plays, west and east — A study in contrasts: An investor’s guide to coalbed methane, A supplement to Oil and Gas Investor, v. 26, no. 12, p. 2-7.Schwochow, S.D., and S.H. Stevens, eds., 1993, Coal-seam water: production, treatment, and disposal: Quarterly Review of Methane from Coal Seams Technology, v. 11, no. 2, p. 1-31.Schwochow, S.D., and S.H. Stevens, eds., 1993, Coal-seam water: production, treatment, and disposal: Quarterly Review of Methane from Coal Seams Technology, v. 11, no. 2, p. 1-31.Schwochow, S.D., and V.F. Nuccio, eds., 2002, Coalbed methane of North America, II: Rocky Mountain Association of Geologists, 108 p.Schwochow, S.D., D.K. Murray, and M.F. Fahy, eds., 1991, Coalbed methane of western North America: Denver, Rocky Mountain Association of Geologists, 336 p.Scotchman, I.C., 1991, Kerogen facies and maturity of the Kimmeridge Clay Formation in southern and eastern England: Marine and Petroleum Geology, v. 8, p. 278-295.

Scott, A.C., 1989, Observations on the nature and origin of fusain: International Journal of Coal Geology, v. 12, p. 443-475.Scott, A.C., 1989, Observations on the nature and origin of fusain: International Journal of Coal Geology, v. 12, p. 443-475.

Scott, A.C., 1991, An introduction to the applications of palaeobotany and palynology to coal geology: Bulletin de la Societe Geologique de France, v. 162, p. 145-153.Scott, A.C., 2002, Coal petrology and the origin of coal macerals: a way ahead?: International Journal of Coal Geology, v. 50, p. 119-134.

Scott, A.C., and A.J. Fleet, eds., 1994, Coal and coal-bearing strata as oil-prone source rocks?: London, The Geological Society Special Publication 77, 213 p.Scott, A.C., and G. Rex, 1985, The formation and significance of Carboniferous coal balls: Philosophical Transactions of the Royal Society of London, B311, p. 123-137.Scott, A.C., and G.M. Rex, 1985, The formation and significance of Carboniferous coal balls: Philosophical Transactions of the Royal Society of London, B 311, p. 123-137.Scott, A.C., and I. J. Glasspool, 2007, Observations and experiments on the origin and formation of inertinite group macerals: International Journal of Coal Geology, v. 70, p. 53-66.Scott, A.C., and I. J. Glasspool, 2007, Observations and experiments on the origin and formation of inertinite group macerals: International Journal of Coal Geology, v. 70, p. 53-66.Scott, A.C., and I.J. Glasspool, 2005, Charcoal reflectance as a proxy for the emplacement temperature of pyroclastic flow deposits: Geology, v. 33, p. 589-592.Scott, A.C., and I.J. Glasspool, 2005, Charcoal reflectance as a proxy for the emplacement temperature of pyroclastic flow deposits: Geology, v. 33, p. 589-592.Scott, A.C., and M.E. Collinson, 1983, Investigating fossil plant beds. Part I: the origin of fossil plants and their sediments: Geology Teaching, v. 7, p. 114-122.Scott, A.C., and T.P. Jones, 1991, Fossil charcoal: a plant fossil record preserved by fire: Geology Today, v. 7, p. 214-216.Scott, A.C., and T.P. Jones, 1994, The nature and influence of fire in Carboniferous ecosystems: Palaeogeography, Palaeoclimatology, Palaeoecology, v. 106, p. 91-112.Scott, A.C., D.P. Mattey, and R. Howard, 1996, New data on the formation of Carboniferous coal balls: Review of Palaeobotany and Palynology, v. 93, p. 317-331.Scott, A.C., D.P. Mattey, and R. Howard, 1996, New data on the formation of Carboniferous coal balls: Review of Palaeobotany and Palynology, v. 93, p. 317-331. (erratum, v. 96, p. 457)Scott, A.C., ed., 1987, Coal and coal-bearing strata: recent advances: Boston, Blackwell Scientific Publications, Geological Society Special Publication 32, 332 p.Scott, A.C., ed., 1987, Coal and coal-bearing strata: recent advances: Boston, Blackwell Scientific Publications, Geological Society Special Publication 32, 332 p.Scott, A.R., 1994, Composition of coalbed gases: In Situ, v. 18, p. 185-208.Scott, A.R., 1997, Timing of cleat development in coal beds (abstract): AAPG Annual Convention Official Program, v. 6, p. A104.

Scott, A.R., 2001, Coal and coalbed methane resources of Texas (abstract): AAPG Bulletin, v. 85, p. 389.Scott, A.R., 2002, Hydrogeologic factors affecting gas content distribution in coal beds: International Journal of Coal Geology, v. 50, p. 363-387.

Scott, A.R., and R. Tyler, 2000, Evaluating coalbed methane potential in Texas (abstract): AAPG Bulletin, v. 84, no. 10, p. 1691.Scott, A.R., and W.R. Kaiser, 1996, Factors affecting gas-content distribution in coal beds: a review: AAPG Rocky Mountain Section Meeting, Expanded abstracts volume, p. 101-106.

Schweinfurth, S.P., 2009, An introduction to coal quality, in B.S. Pierce and K.O. Dennen, eds., The National Coal Resource Assessment overview: U.S. Geological Survey Professional Paper 1625-F, p. 1-16.

Scott, A.C., 1989, Deltaic coals: an ecological and palaeobotanical perspective, in M.K.G. Whateley and K.T. Pickering, eds., Deltas, sites and traps for fossil fuels: Boston, Blackwell Scientific Publications, Geological Society Special Publication 41, p. 309-316.

Scott, A.C., 1990, Anatomical preservation of fossil plants, in D.E.G. Briggs and P.R. Crowther, eds., Palaeobiology, a synthesis: Boston, Blackwell Scientific Publications, p. 263-266.Scott, A.C., 1991, An introduction to the applications of palaeobotany and palynology to coal geology, in P. Bertrand, ed., Coal: formation, occurrence and related properties: Bulletin de la Societe Geologique de France, v. 162, p. 145-153.

Scott, A.C., and A.J. Fleet, 1994, Coal and coal-bearing strata as oil-prone source rocks: current problems and future directions, in A.C. Scott and A.J. Fleet, eds., Coal and coal-bearing strata as oil-prone source rocks?: London, The Geological Society Special Publication 77, p. 201-205.

Scott, A.R., 1999, Improving coal gas recovery with microbially enhanced coalbed methane, in M. Mastalerz, M. Glikson, and S.D. Golding, eds., Coalbed methane: scientific, environmental and economic evaluation: Boston, Kluwer Academic Publishers, p. 89-110.

Scott, A.R., 2003, Coalbed methane potential of the Gulf Coast region, in M.R. Silverman, ed., Emerging coalbed methane plays of North America (part 2): Denver, CO, Petroleum Frontiers, v. 18, no. 4, p. 38-46.Scott, A.R., 2009, Developing exploration strategies for coal-bed methane and shale gas reservoirs, in T. Carr, T. D’Agostino, W. Ambrose, J. Pashin, and N.C. Rosen, eds., Unconventional energy resources: making the unconventional conventional: 29 th Annual GCSSEPM Foundation Bob F. Perkins Research Conference, CD-ROM, p. 303-305.Scott, A.R., and M. Hussain, 1988, Organic geochemistry, source rock potential, and oil-source rock correlation of the Permian Spraberry Formation, northern Midland basin, Jo Mill Field, Borden County, Texas, in B.K. Cunningham, ed., Permian and Pennsylvanian stratigraphy, Midland basin, west Texas: studies to aid hydrocarbon exploration: SEPM Permian Basin, Publication 88-28, p. 33-51.

Scott, A.R., H.S. Nance, and M.Z. Beltran, 1997, Heterogeneity of water and coal gas production in the northern San Juan basin, Colorado and New Mexico: International Coalbed Methane Symposium, Paper 9739, 11 p.Scott, A.R., H.S. nance, and M.Z. Beltran, 1997, Heterogeneity of water and coal gas production in the northern San Juan basin, Colorado and New Mexico: International Coalbed Methane Symposium, Paper 9739, 11 p.Scott, A.R., N. Zhou, and J.R. Levine, 1995, A modified approach to estimating coal and coal gas resources: example from the Sand Wash Basin, Colorado: AAPG Bulletin, v. 79, p. 1320-1336.

Scott, A.R., W.R. Kaiser, and W.B. Ayers, Jr., 1994, Thermogenic and secondary biogenic gases, San Juan basin, Colorado and New Mexico -- implications for coalbed gas producibility: AAPG Bulletin, v. 78, no. 8, p. 1186-1209.Scott, D., 1994, Developments affecting metallurgical uses of coal: IEA Coal Research, Publication IEACR/74, 92 p.Scott, J., 1992, Accurate recognition of source rock character in the Jurassic of the North West Shelf, western Australia: The APEA Journal, v. 32, part 1, p. 289-299. (problems of Rock-Eval technique)Scott, R.R., 2003, Assessment of CO2 sequestration and ECBM potential of U.S. coalbeds: U.S. Department of Energy Report No. DE-FC26-00NT40924.Scott, S., B. Anderson, P. Crosdale, J. Dingwall, and G. Leblang, 2007, Coal petrology and coal seam gas contents of the Walloon subgroup—Surat Basin, Queensland, Australia: International Journal of Coal Geology, v. 70, p. 209-222.

Sechman, H., M.J. Kotarba, J. Fiszer, and M. Dzieniewicz, 2013, Distribution of methane and carbon dioxide concentrations in the near-surface zone and their genetic characterization at the abandoned "Nowa Ruda" coal mine (Lower Silesian Coal Basin, SW Poland): International Journal of Coal Geology, v. 116-117, p. 1-16.Seewald, J.S., and L.B. Eglinton, 1994, Organic-inorganic interactions during vitrinite maturation: Constraints from hydrous pyrolysis experiments (abstract): The Society for Organic Petrology, Annual Meeting Abstracts, v. 11, p. 91-94.Seewald, J.S., and L.B. Eglinton, 2000, An experimental study of organic-inorganic interactions during vitrinite maturation: Geochimica et Cosmochimica Acta, v. 64, p. 1577-1591.Seewald, J.S., L.B. Eglinton, and Y.-L. Ong, 2000, An experimental study of organic-inorganic interactions during vitrinite maturation: Geochimica et Cosmochimica Acta, v. 64, p. 1577-1591.Seidle, J., 2011, Fundamentals of coalbed methane reservoir engineering: Tulsa, OK, PennWell Books, 401 p.

Selden, R.F., 1934, The occurrence of gases in coals: U.S. Bureau of Mines Report of Investigations 3233, 64 p.

Selvig, W.A., 1945, Resins of coal: U.S. Bureau of Mines Technical Paper 680, 24 p.

Sen Gupta, S., and B. Bardhan, 2005, Petrographic atlas of Indian coal: Geological Survey of India Catalogue Series 7, 150 p.Sen, S., 1992, Usefulness of petrographic classification in defining national coal resources: International Journal of Coal Geology, v. 20, p. 263-275.

Sener, M., and M.N. Gundogdu, 1996, Geochemical and petrographic investigation of Himmetoglu oil shale, Goynuk, Turkey: Fuel, v. 75, p. 1313-1322.Senftle, J., 1989, Influence of kerogen isolation methods on petrographic and bulk chemical composition of a Woodford Shale sample: TSOP Newsletter, v. 6, no. 4, p. 7-9.Senftle, J., 1989, Influence of kerogen isolation methods on petrographic and bulk chemical composition of a Woodford Shale sample: TSOP Research Subcommittee Report.Senftle, J.T., 1987, Organic petrography; an old dog with new tricks for petroleum geochemistry (abstract): AAPG Bulletin, v. 71, p. 612-613.Senftle, J.T., 1987, Perspective on vitrinite reflectance analysis as a thermal maturity parameter: TSOP Newsletter, v. 4, no. 3, p. 2-3.Senftle, J.T., and A. Davis, 1982, Relationships between coal constitution, thermoplastic properties and liquefaction behavior of coals and vitrinite concentrates from the Lower Kittanning seam: The Pennsylvania State University, Coal Research Section, Report DOE-30013-FI.Senftle, J.T., and A. Davis, 1984, Effect of oxidative weathering on the thermoplastic and liquefaction behaviors of four coals: International Journal of Coal Geology, v. 3, p. 375-381.Senftle, J.T., and A. Davis, 1984, Effect of oxidative weathering on the thermoplastic and liquefaction behaviors of four coals: International Journal of Coal Geology, v. 3, p. 375-381.

Senftle, J.T., and S.R. Larter, 1988, A discussion of modern resin and fossil resinite fluorescence: Organic Geochemistry, v. 12, p. 419-420.Senftle, J.T., and S.R. Larter, 1988, The geochemistry of exinites—1. Evaluation of spectral fluorescence of a series of modern resins and fossil resinites: Organic Geochemistry, v. 13, p. 973-980.

Senftle, J.T., J.H. Brown, and S.R. Larter, 1987, Refinement of organic petrographic methods for kerogen characterization: International Journal of Coal Geology, v. 7, p. 105-117.

Scott, A.R., W.R. Kaiser, and W.B. Ayers, Jr., 1991, Composition, distribution, and origin of Fruitland Formation and Pictured Cliffs Sandstone gases, San Juan basin, Colorado and New Mexico, in S.D. Schwochow, D.K. Murray, and M.F. Fahy, eds., Coalbed methane of western North America: Denver, Rocky Mountain Association of Geologists, p. 93-108.

Scotti, P., and R. Fantoni, 2012, Evaluation of the heat flow in the southern Alps during Mesozoic extension: Implications for hydrocarbon exploration in the PO Plain foredeep, in N.B. Harris and K.E. Peters, eds., Analyzing the thermal history of sedimentary basins: Methods and case studies: SEPM Special Publication 103, p. 153-165.

Seidle, J.P., 2002, Lessons learned, lessons lost — review of selected coalbed methane pilots, in S.D. Schwochow and V.F. Nuccio, eds., Coalbed methane of North America, II: Rocky Mountain Association of Geologists, p. 7-16.Selcuk, N., 1988, Fluidized bed combustion of coal, in Yuda Yurum, ed., New trends in coal science: Boston, Kluwer Academic Publishers, p. 481-494.

Self, J.G., R.T. Ryder, R.C. Johnson, M.E. Brownfield, and T.J. Mercier, 2011, Stratigraphic cross sections of the Eocene Green River Formation in the Green River Basin, southwestern Wyoming, northwestern Colorado, and northeastern Utah: U.S. Geological Survey, Digital Data Series DDS-69-DD, chapter 5, 11 p. http://pubs.usgs.gov/dds/dds-069/dds-069-dd/REPORTS/69_DD_CH_5.pdf

Semmelbeck, M.E., and W.J. Lee, 1992, Well test requirements for evaluation of coalbed methane development potential, in Coalbed methane: Society of Petroleum Engineers, Reprint Series 35, p. 90-101.

Sen, S., and M. Sen, 1996, Depositional model vis-à-vis composition and hydrocarbon potentiality of some Indian Lower Gondwana coals, in Gondwana nine (v.2): Geological Survey of India, Ninth International Gondwana Symposium, p. 1273-1278.

Senftle, J.T., and C.R. Landis, 1991, Vitrinite reflectance as a tool to assess thermal maturity, in R.K. Merrill, ed., Source and migration processes and evaluation techniques: AAPG Treatise of Petroleum Geology, Handbook of Petroleum Geology, p. 119-125.Senftle, J.T., and C.R. Landis, 1991, Vitrinite reflectance as a tool to assess thermal maturity, in R.K. Merrill, ed., Source and migration processes and evaluation techniques: AAPG Treatise of Petroleum Geology, Handbook of Petroleum Geology, p. 119-125.

Senftle, J.T., C.R. Landis, and R.L. McLaughlin, 1993, Organic petrographic approach to kerogen characterization, in M.H. Engel and S.A. Macko, eds., Organic geochemistry, principles and applications: New York, Plenum Press, p. 355-374.Senftle, J.T., C.R. Landis, and R.L. McLaughlin, 1993, Organic petrographic approach to kerogen characterization, in M.H. Engel and S.A. Macko, eds., Organic geochemistry: New York, Plenum Press, p. 355-374.Senftle, J.T., C.R. Landis, and R.L. McLaughlin, 1993, Organic petrographic approach to kerogen characterization, in M.H. Engel and S.A. Macko, eds., Organic geochemistry: New York, Plenum Press, p. 355-374.Senftle, J.T., C.R. Landis, and R.L. McLaughlin, 1993, Organic petrographic approach to kerogen characterization, in M.H. Engel, and S.A. Macho, eds., Organic geochemistry: principles and applications: New York, Plenum Press, p. 355-374.

Senftle, J.T., J.H. Brown, and S.R. Larter, 1987, Refinement of organic petrographic methods for kerogen characterization: International Journal of Coal Geology, v. 7, p. 105-117.Senftle, J.T., K.L. Yordy, L.S. Barron, and J.C. Crelling, 1991, Whole rock and isolated kerogen characterization studies: observations of sample type preparations upon petrographic and chemical characterization of New Albany Shale (abstract): Organic Geochemistry, v. 17, p. 275.Senftle, J.T., X. Wang, and I. Lerche, 1990, Normalized power spectrum of fluorescence spectra alteration: a method of characterizing resins and resinite kerogens: International Journal of Coal Geology, v. 15, p. 53-61.Senftle, J.T., X. Wang, and I. Lerche, 1990, Normalized power spectrum of fluorescence spectra alteration: a method of characterizing resins and resinite kerogens: International Journal of Coal Geology, v. 15, p. 53-61.Senior, C.L., C.J. Bustard, H. Durham, K. Baldrey, and D. Michaud, 2004, Characterization of fly ash from full-scale demonstration of sorbent injection for mercury control on coal-fired power plants: Fuel Processing Technology, v. 85, p. 601-612.

Sentorun, C., A. Ersoy-Mericboyu, A. Kaso, and S. Kűcűkbayrak, 1995, Carbonization behavior of some Turkish lignites, effect of mineral matter: Erdöl und Kohle-Erdgas-Petrochemie, v. 48, no. 1, p. 39-42.Seredin, V.V., 1996, Rare earth element-bearing coals from the Russian Far East deposits: International Journal of Coal Geology, v. 30, p. 101-129.Seredin, V.V., 2012, From coal science to metal production and environmental protection: A new story of success: International Journal of Coal Geology, v. 90-91, p. 1-3. (Germanium)Seredin, V.V., and R.B. Finkelman, 2008, Metalliferous coals: A review of the main genetic and geochemical types: International Journal of Coal Geology, v. 76, p. 253-289.Seredin, V.V., and R.B. Finkelman, 2008, Metalliferous coals: A review of the main genetic and geochemical types: International Journal of Coal Geology, v. 76, p. 253-289.Seredin, V.V., and S. Dai, 2012, Coal deposits as potential alternative sources for lanthanides and yttrium: International Journal of Coal Geology, v. 94, p. 67-93.Seredin, V.V., S. Dai, Y. Sun, and I.Y. Chekryzhov, 2013, Coal deposits as promising sources of rare metals for alternative power and energy-efficient technologies: Applied Geochemistry, v. 31, p. 1-11.Sever, M., 2006, Coalbed gas enters the energy mix: Geotimes, v. 51, no. 9, p. 30-33.

Shah, K., R. Atkin, R. Stanger, T. Wall, and B. Moghtaderi, 2014, Interactions between vitrinite and inertinite-rich coals and the ionic liquid – [bmim][Cl]: Fuel, v. 119, p. 214-218.Shah, S., and K. Totlani, 2014, Difficulties and prospects of coalbed methane in India as compared to North America: Journal of Unconventional Oil and Gas Resources, v. 6, p. 48-53.Shalaby, M.R., M.H. Hakimi, and W.H. Abdullah, 2012, Geochemical characterization of solid bitumen (migrabitumen) in the Jurassic sandstone reservoir of the Tut field, Shushan Basin, northern western desert of Egypt: International Journal of Coal Geology, v. 100, p. 26-39. (reservoir solid bitumen)Shalaby, M.R., M.H. Hakimi, and W.H. Abdullah, 2012, Organic geochemical characteristics and interpreted depositional environment of the Khatatba Formation, northern Western Desert, Egypt: AAPG Bulletin, v. 96, p. 2019-2036.Shalaby, M.R., M.H. Hakimi, and W.H. Abdullah, 2012, Organic geochemical characteristics and interpreted depositional environment of the Khatatba Formation, northern Western Desert, Egypt: AAPG Bulletin, v. 96, p. 2019-2036.Shalaby, M.R., M.H. Hakimi, and W.H. Abdullah, 2012, Organic geochemical characteristics and interpreted depositional environment of the Khatatba Formation, northern Western Desert, Egypt: AAPG Bulletin, v. 96, p. 2019-2036.Shanmugam, G., 1985, Significance of coniferous rain forests and related organic matter in generating commercial quantities of oil, Gippsland basin, Australia: AAPG Bulletin, v. 69, p. 1241-1254.Shao, L. P. Zhang, J. Hilton, R. Gayer, Y. Wang, C. Zhao, and Z. Luo, 2003, Paleoenvironments and paleogeography of the Lower and lower Middle Jurassic coal measures in the Turpan-Hami oil-prone coal basin, northwestern China: AAPG Bulletin, v. 87, p. 335-355.Shao, L., P. Zhang, R.A. Gayer, J. Chen, and S. Dai, 2003, Coal in a carbonate sequence stratigraphic framework: the Upper Permian Heshan Formation in central Guangxi, southern China: Journal of the Geological Society, London, v. 160, p. 285-298.Shargorodskiy, I.Y., 1986, Conditions of formation of bitumen vein deposits in the western Urals: International Geology Review, v. 28, p. 684-690.Sharp, P.A., 1986, Storage of 8 mesh sub-bituminous coal: Journal of Coal Quality, v. 5, p. 131-132.Shaver, S.A., J.C. Hower, C.F. Eble, E.D. McLamb, and K. Kuers, 2006, Trace element geochemistry and surface water chemistry of the Bon Air coal, Franklin County, Cumberland Plateau, southeast Tennessee: International Journal of Coal Geology, v. 67, p. 47-78.Shearer, J.C., 1994, Thoughts on the origin of inertinite-rich coals: TSOP Newsletter, v. 11, nos. 3-4, p. 9.Shearer, J.C., 1995, More thoughts on oxidized material in peat and coal: TSOP Newsletter, v. 12, no. 3, p. 13.

Shearer, J.C., and T.A. Moore, 1994, Grain-size and botanical analysis of two coal beds from the south island of New Zealand: Review of Palaeobotany and Palynology, v. 80, p. 85-114.Shearer, J.C., and T.A. Moore, 1996, Effects of experimental coalification on texture, composition and compaction of Indonesian peat and wood: Organic Geochemistry, v. 24, p. 127-140.Shearer, J.C., J.R. Staub, and T.A. Moore, 1994, The conundrum of coal bed thickness: a theory for stacked mire sequences: Journal of Geology, v. 102, p. 611-617.Shearer, J.C., T.A. Moore, and T.D. Demchuk, 1995, Delineation of the distinctive nature of Tertiary coal beds: International Journal of Coal Geology, v. 28, p. 71-98.Shen, J., Y. Qin, G.X. Wang, X. Fu, C. Wei, and B. Lei, 2011, Relative permeabilities of gas and water for different rank coals: International Journal of Coal Geology, v. 86, p. 266-275.Sheridan, E.T., and J.A. DeCarlo, 1965, Coal carbonization in the United States, 1900-62: U.S. Bureau of Mines, Information Circular 8251, 83 p.Sherwood, N.R., A.C. Cook, M. Gibling, and C. Tantisukrit, 1984, Petrology of a suite of sedimentary rocks associated with some coal-bearing basins in northwestern Thailand: International Journal of Coal Geology, v. 4, p. 45-71.Sherwood, N.R., and A.C. Cook, 1983, Petrology of organic matter in the Toolebuc Formation oil shales: Proceedings, First Australian workshop on oil shale, CSIRO Division of Energy Chemistry, NSW, Australia, p. 35-38.Sherwood, N.R., and A.C. Cook, 1984, Low rank oil shales: part 1—organic petrology: The University of Wollongong, Department of Geology, Final Project Report to the Department of National Development and Energy on NERD&D Program Project 79/9014, 320 p.

Sherwood, N.R., with contributions from A.C. Cook, 1984, Low rank oil shales: part I - organic petrology: The University of Wollongong, Department of Geology, Final Project Report, 320 p.

Senior, W.J., J.D. Kantorowicz, and I.W. Wright, 2010, Geological storage of carbon dioxide: an emerging opportunity, in B.A. Vining and S.C. Pickering, eds., Petroleum geology: from mature basins to new frontiers: London, Geological Society, Proceedings of the 7 th Petroleum Geology Conference, p. 1165-1169.

Seyer, W.F., 1952, The origin and transformation of bituminous material in coal, in Second conference of the origin and constitution of coal: Nova Scotia Department of Mines, p. 319-340.

Shearer, J.C., and T.A. Moore, 1992, Why are some coals banded? (abstract): TSOP 9 th Annual Meeting Abstracts and Program, p. 95-98. (vitrain formed from secondary xylem tissue)

Sherwood, N.R., and A.C. Cook, 1986, Organic matter in the Toolebuc Formation, in D.I. Gravestock, P.S. Moore, and G.M. Pitt, eds., Contributions to the geology and hydrocarbon potential of the Eromanga basin: Geological Society of Australia Special Publication 12, p. 255-265.

Shewchuk, C., 2006, Managing logistics of CBM extraction: Hart’s E&P, v. 79, no. 9, p. 17-19.Shi, J.Q., and S. Durucan, 2001, Application of conventional oil reservoir productivity equations to horizontal coalbed methane wells: Tuscaloosa, Alabama, Proceedings, International Coalbed Methane Symposium, Paper 134, p. 221-232.Shi, J.Q., and S. Durucan, 2001, Identifying the key factors controlling openhole cavity completions at the San Juan basin — a numerical study: Tuscaloosa, Alabama, Proceedings, International Coalbed Methane Symposium, Paper 135, p. 233-244.Shi, J.Q., and S. Durucan, 2003, A bidisperse pore diffusion model for methane displacement desorption in coal by CO2 injection: Fuel, v. 82, p. 1219-1229.Shi, J.Q., and S. Durucan, 2003, A bidisperse pore diffusion model for methane displacement desorption in coal by CO2 injection: Fuel, v. 82, p. 1219-1229.Shi, J.Q., S. Durucan, and I.C. Sinka, 2002, Key parameters controlling coalbed methane cavity well performance: International Journal of Coal Geology, v. 49, p. 19-31.Shi, J.Q., S. Durucan, and S. Shimada, 2014, How gas adsorption and swelling affects permeability of coal: A new modelling approach for analyzing laboratory test data: International Journal of Coal Geology, v. 128-129, p. 134-142.Shi, J.Q., S. Durucan, and S. Shimada, 2014, How gas adsorption and swelling affects permeability of coal: A new modelling approach for analyzing laboratory test data: International Journal of Coal Geology, v. 128-129, p. 134-142.Shibaoka, M., 1978, Micrinite and exudatinite in some Australian coals, and their relation to the generation of petroleum: Fuel, v. 57, p. 73-77.Shibaoka, M., 1978, Occurrence of ‘exudatinite’ in brown coals: Fuel, v. 57, p. 798-799.Shibaoka, M., 1981, Behavior of vitrinite macerals in some organic solvent in the autoclave: Fuel, v. 60, p. 240-246.Shibaoka, M., 1983, Genesis of micrinite in some Australian coals: Fuel, v. 62, p. 639-644.Shibaoka, M., 1985, Microscopic investigation of unburnt char in fly ash: Fuel, v. 64, p. 263-269.Shibaoka, M., 1985, Microscopic observation of the swelling and dissolution of coal by tetralin during the early stages of hydrogenation: Fuel, v. 64, p. 606-612.

Shibaoka, M., A.J.R. Bennett, and H. Echigo, 1981, Some characteristics of Wandoan coal in relation to hydrogenation: Fuel, v. 61, p. 265.Shibaoka, M., and S. Ueda, 1978, Formation and stability of mesophase during coal hydrogenation: Fuel, v. 57, p. 667-675.

Shibaoka, M., J.F. Stephens, and N.J. Russell, 1979, Microscopic observations of the swelling of a high-volatile bituminous coal in response to organic solvents: Fuel, v. 58, p. 515-522.Shirley, K., 1999, Exceptional economics, potential drive coalbed methane plays: American Oil & Gas Reporter, v. 42, no. 7, p. 113-119. (Rocky Mountain basins)Shirley, K., 2002, Operators continue to expand coalbed methane’s geographic diversity: American Oil & Gas Reporter, v. 45, no. 3, p. 88-103.Shoko, E., B. McLellan, A.L. Dicks, J.C. Diniz da Costa, 2006, Hydrogen from coal: production and utilization technologies: International Journal of Coal Geology, v. 65, p. 213-222.Shukla, R., P. Ranjith, A. Haque, and X. Choi, 2010, Review article: A review of studies on CO2 sequestration and caprock integrity: Fuel, v. 89, p. 2651-2664.Shurtleff, K., and D. Doyle, 2008, Single well, single gas phase technique is key to unique method of extracting oil vapors from oil shale: World Oil, v. 229, no. 3, p. 118-122, 127.Sia, S.-G., and W.H. Abdullah, 2011, Concentration and association of minor and trace elements in Mukah coal from Sarawak, Malaysia, with emphasis on the potentially hazardous trace elements: International Journal of Coal Geology, v. 88, p. 179-193.Sia, S.-G., and W.H. Abdullah, 2012, Enrichment of arsenic, lead, and antimony in Balingian coal from Sarawak, Malaysia: Modes of occurrence, origin, and partitioning behaviour during coal combustion: International Journal of Coal Geology, v. 101, p. 1-15.Sia, S.-G., and W.H. Abdullah, 2012, Enrichment of arsenic, lead, and antimony in Balingian coal from Sarawak, Malaysia: Modes of occurrence, origin, and partitioning behaviour during coal combustion: International Journal of Coal Geology, v. 101, p. 1-15.Sia, S.G., and W.H. Abdullah, 2012, Geochemical and petrographical characteristics of low-rank Balingian coal from Sarawak, Malaysia: Its implications on depositional conditions and thermal maturity: International Journal of Coal Geology, v. 96-97, p. 22-38.Sia, S.-G., and W.H. Abdullah, 2012, Geochemical and petrographical characteristics of low-rank Balingian coal from Sarawak, Malaysia: Its implications on depositional conditions and thermal maturity: International Journal of Coal Geology, v. 96-97, p. 22-38.Siavalas, G., M. Linou, A. Chatziapostolou, S. Kalaitzidis, H. Papaefthymiou, and K. Christanis, 2009, Palaeoenvironment of Seam I in the Marathousa lignite mine, Megalopolis Basin (southern Greece): International Journal of Coal Geology, v. 78, p. 233-248.Siebert, J., 1990, Monitoring coal seam properties; in situ test and measuring methods: Erdöl und Kohle-Erdgas-Petrochemie, v. 43, p. 181-186.Siemons, N., and A. Busch, 2007, Measurement and interpretation of supercritical CO2 sorption on various coals: International Journal of Coal Geology, v. 69, p. 229-242.Siemons, N., and A. Busch, 2007, Measurement and interpretation of supercritical CO2 sorption on various coals: International Journal of Coal Geology, v. 69, p. 229-242.Siemons, N., K.-H. A.A. Wolf, and J. Bruining, 2007, Interpretation of carbon dioxide diffusion behavior in coals: International Journal of Coal Geology, v. 72, p. 315-324.Sikander, A.H., and J.L. Pittion, 1978, Reflectance studies on organic matter in Lower Paleozoic sediments of Quebec: Bulletin of Canadian Petroleum Geology, v. 26, p. 132-151.Sikander, A.H., and J.L. Pittion, 1978, Reflectance studies on organic matter in lower Paleozoic sediments of Quebec: Bulletin of Canadian Petroleum Geology, v. 26, p. 132-151.Silva, L.F.O., C.H. Sampaio, A. Guedes, S. Fdez-Ortiz de Vallejuelo, and J.M. Madariaga, 2012, Multianalytical approaches to the characterization of minerals associated with coals and the diagnosis of their potential risk by using combined instrumental microspectroscopic techniques and thermodynamic speciation: Fuel, v. 94, p. 52-63.Silva, L.F.O., M.L.S. Oliveira, E.R. Neace, J.M.K. O’Keefe, K.R. Henke, and J.C. Hower, 2011, Nanominerals and ultrafine particles in sublimates from the Ruth Mullins coal fire, Perry County, eastern Kentucky, USA: International Journal of Coal Geology, v. 85, p. 237-245.Silva, L.F.O., M.L.S. Oliveira, V. Philippi, C. Serra, S. Dai, W. Xue, W. Chen, J.M.K. O’Keefe, C.S. Romanek, S.G. Hopps, and J.C. Hower, 2012, Geochemistry of carbon nanotube assemblages in coal fire soot, Ruth Mullins fire, Perry County, Kentucky: International Journal of Coal Geology, v. 94, p. 206-213.Silva, L.F.O., M.L.S. Oliveira, V. Philippi, C. Serra, S. Dai, W. Xue, W. Chen, J.M.K. O’Keefe, C.S. Romanek, S.G. Hopps, and J.C. Hower, 2012, Geochemistry of carbon nanotube assemblages in coal fire soot, Ruth Mullins fire, Perry County, Kentucky: International Journal of Coal Geology, v. 94, p. 206-213.Silva, M.B., and W. Kalkreuth, 2005, Petrological and geochemical characterization of Candiota coal seams, Brazil — Implications for coal facies interpretations and coal rank: International Journal of Coal Geology, v. 64, p. 217-238.

Shibaoka, M., 1985, The influence of rank and maceral composition on combustion of pulverized coal, in International conference on coal science, 1985: Oxford, Pergamon Press, p. 665-668.

Shibaoka, M., C.G. Thomas, and E. Gawronski, 1989, Microscopic investigations of combustion residues of inertinite rich coals from laboratory and power station samples, in C.G. Thomas and M.G. Strachan, eds., Proceedings of the macerals ’89 symposium: North Ryde, NSW, CSIRO, p. 3-1 to 3-18.

Silva, M.B., W. Kalkreuth, and M. Holz, 2008, Coal petrology of coal seams from the Leão-Butiá coalfield, Lower Permian of the Paraná Basin, Brazil—Implications for coal facies interpretations: International Journal of Coal Geology, v. 73, p. 331-358.Silva, R., M. Pires, C.M.N. Azevedo, L. Fagundes, L. Garavaglia, and C.J.B. Gomes, 2010, Monitoring light hydrocarbons in Brazilian coal mines and in confined coal samples: International Journal of Coal Geology, v. 84, p. 269-275.

Silverman, M.R., ed., 2001, Emerging coalbed methane plays of North America: Denver, CO, IHS Energy Group, Petroleum Frontiers, v. 18, no. 3, 60 p.Silverman, M.R., ed., 2003, Emerging coalbed methane plays of North America (part 3): Petroleum Frontiers, v. 19, no. 2, 38 p.Simons, N., and A. Busch, 2007, Measurement and interpretation of supercritical CO2 sorption on various coals: International Journal of Coal Geology, v. 69, p. 229-242.Sinayuç, Ç., and F. Gűmrah, 2009, Modeling of ECBM recovery from Amasra coalbed in Zonguldak Basin, Turkey: International Journal of Coal Geology, v. 77, p. 162-174.

Singer, D. A., and C.M. McCulloch, 1969, Probability tables for locating elliptical targets with square, rectangular, and hexagonal pointnets: Pennsylvania State Univ., Mineral Experimental Station, Special Publication 1-69, 100 p.Singer, S., 1984, Pulverized coal combustion: recent developments: Park Ridge, New Jersey, Noyes Publications, 184 p.Singh, A., 2002, On a striking fluorescing microcomponent from Indian Tertiary lignites: International Journal of Coal Geology, v. 51, p. 59-65.Singh, A.K., M. Sharma, and M.P. Singh, 2008, Genesis of natural cokes: some Indian examples: International Journal of Coal Geology, v. 75, p. 40-48.Singh, A.K., M. Sharma, and M.P. Singh, 2013, SEM and reflected light petrography: A case study on natural cokes from seam XIV, Jharia coalfield, India: Fuel, v. 112, p. 502-512.Singh, A.K., M.P. Singh, M. Sharma, and S.K. Srivastava, 2007, Microstructures and microtextures of natural cokes: A case study of heat-affected coking coals from the Jharia coalfield, India: International Journal of Coal Geology, v. 71, p. 153-175.Singh, A.K., R.V.K. Singh, M.P. Singh, H. Chandra, and N.K. Shukla, 2007, Mine fire gas indices and their application to Indian underground coal mine fires: International Journal of Coal Geology, v. 69, p. 192-204.Singh, M.P., and G.P. Singh, 1995, Petrological evolution of the Paleogene coal deposits of Jammu, Jammu and Kashmir, India: International Journal of Coal Geology, v. 27, p. 171-199.Singh, P.K., M.P. Singh, and A.K. Singh, 2010, Petro-chemical characterization and evolution of Vastan lignite, Gujarat, India: International Journal of Coal Geology, v. 82, p. 1-16.Singh, P.K., M.P. Singh, P.K. Prachiti, M.S. Kalpana, C. Manikyamba, G. Lakshminarayana, A.K. Singh, and A.S. Naik, 2012, Petrographic characteristics and carbon isotopic composition of Permian coal: Implications on depositional environment of Sattupalli coalfield, Godavari Valley, India: International Journal of Coal Geology, v. 90-91, p. 34-42.Singh, R.M., and C.S. Cwivedi, 1994, A study of coal facies in the Korba sub-basin, Mahanadi Valley, India: International Journal of Coal Geology, v. 25, p. 113-132.Singh, R.N., 1986, A practical system of classifying coal seams liable to spontaneous combustion: Journal of Coal Quality, v. 5, p. 108-113.Singh, R.N., 1986, A practical system of classifying coal seams liable to spontaneous combustion: Journal of Coal Quality, v. 5, p. 108-113.Singh, S., L.C. Ram, R.E. Masto, and S.K. Verma, 2011, A comparative evaluation of minerals and trace elements in the ashes from lignite, coal refuse, and biomass fired power plants: International Journal of Coal Geology, v. 87, p. 112-120.Singh, S., L.C. Ram, R.E. Masto, and S.K. Verma, 2011, A comparative evaluation of minerals and trace elements in the ashes from lignite, coal refuse, and biomass fired power plants: International Journal of Coal Geology, v. 87, p. 112-120.Singh, S., L.C. Ram, R.E. Masto, and S.K. Verma, 2011, A comparative evaluation of minerals and trace elements in the ashes from lignite, coal refuse, and biomass fired power plants: International Journal of Coal Geology, v. 87, p. 112-120.Singha, B.B., and S. Maharaj, 1993, A novel and rapid method for estimation of sulphur in coal: Fuel Science and Technology, v. 12, p. 53.Sinninghe Damsté, J.S., W.I.C. Rijpstra, and G.-J. Reichart, 2002, The influence of oxic degradation on the sedimentary biomarker record, II. Evidence from Arabian Sea sediments: Geochimica et Cosmochimica Acta, v. 66, p. 2737-2754.Siriwardane, H., I. Haljasmaa, R. McLendon, G. Irdi, Y. Soong, and G. Bromhal, 2009, Influence of carbon dioxide on coal permeability determined by pressure transient methods: International Journal of Coal Geology, v. 77, p. 109-118.Siriwardane, H.J., B.D. Bowes, G.S. Bromhal, R.K. Gondle, A.W. Wells, and B.R. Strazisar, 2012, Modeling of CBM production, CO2 injection, and tracer movement at a field CO2 sequestration site: International Journal of Coal Geology, v. 96-97, p. 120-136.Siriwardane, H.J., B.D. Bowes, G.S. Bromhal, R.K. Gondle, A.W. Wells, and B.R. Strazisar, 2012, Modeling of CBM production, CO2 injection, and tracer movement at a field CO2 sequestration site: International Journal of Coal Geology, v. 96-97, p. 120-136.Siriwardane, H.J., R.K. Gondle, and D.H. Smith, 2009, Shrinkage and swelling of coal induced by desorption and sorption of fluids: Theoretical model and interpretation of a field project: International Journal of Coal Geology, v. 77, p. 188-202.Sitler, J.A., 1979, Effects of source material on vitrinite reflectance: Morgantown, WV, unpublished M.S. thesis, West Virginia University, 108 p.Sivaraman, R., 2003, The potential role of hydrate technology in sequestering carbon dioxide: GasTIPS, v. 9, no. 4, p. 4-7.Sivek, M., M. Čáslavský, and J. Jirásek, 2008, Applicability of Hilt’s law to the Czech part of the Upper Silesian coal basin (Czech Republic): International Journal of Coal Geology, v. 73, p. 185-195.Sivek, M., M. Čáslavský, and J. Jirásek, 2008, Applicability of Hilt’s law to the Czech part of the Upper Silesian coal basin (Czech Republic): International Journal of Coal Geology, v. 73, p. 185-195.

Skolnick, H., 1958, Observations on fusain: American Association of Petroleum Geologists Bulletin, v. 42, p. 2223-2236.Skorupska, N.M., A. Sanyal, G.J. Hesselman, J.C. Crelling, I.A.S. Edwards, and H. Marsh, 1987, The use of an entrained flow reactor to assess the reactivity of coals of high inertinite content: Proceedings International Conference on Coal Science, The Netherlands, Elsevier, p. 827-831.Sladek, T.A., 1975, Recent trends in oil shale—part 3. Shale oil refining and some oil shale problems: Colorado School of Mines Research Institute, Mineral Industries Bulletin, v. 18, no. 2.

Sloss, L., 1996, Residues from advanced coal-use technologies: London, IEA Coal Research, IEA Coal Research Perspectives Series, IEAPER/30, 40 p.

Silverman, M.R., 2001, Emerging coalbed methane plays of North America, in M.R. Silverman, ed., Emerging coalbed methane plays of North America: Denver, CO, Petroleum Frontiers, v. 18, no. 3, p. 1-10.Silverman, M.R., 2003, Emerging coalbed methane plays of North America, in M.R. Silverman, ed., Emerging coalbed methane plays of North America (part 2): Denver, CO, Petroleum Frontiers, v. 18, no. 4, p. vi-viii.

Sinclair, J.F., 2005, Coalbed-methane potential in Osage County, Oklahoma (abstract), in B.J. Cardott, ed., Unconventional energy resources in the southern Midcontinent, 2004 symposium: Oklahoma Geological Survey Circular 110, p. 105.

Skidmore, D., 1976, Agglomeration as a factor in the non-catalytic liquefaction of coal, in C.J. Smith, compiler, Proceedings of the coal agglomeration and conversion symposium: West Virginia Geological and Economic Survey, p. 135-145.

Sloan, G.R., B.W. McKinstry, P.G. Gagnon, F.M. Dawson, and J.A. Lee, 2003, Coalbed methane in western Canada, in M.R. Silverman, ed., Emerging coalbed methane plays of North America, part 1: Petroleum Frontiers, v. 18, no. 3, p. 11-28.

Sloss, L.L., 1995, Mercury emissions and effects — the role of coal: IEA Coal Research, Perspectives Series, IEAPER/19, 39 p.Sloss, L.L., and I.M. Smith, 1993, Organic compounds from coal utilization: IEA Coal Research, IEACR/63, 69 p.Sloss, L.L., and I.M. Smith, 1993, Organic compounds from coal utilization: London, IEA Coal Research, IEACR/63, 69 p.Sloss, L.L., I.M. Smith, and D.M.B. Adams, 1996, Pulverized coal ash — requirements for utilisation: London, IEA Coal Research, IEA Coal Research Report Series, IEACR/88, 88 p.Smędowski, Ł., and M. Krzesińska, 2013, Molecular oriented domains (MOD) and their effect on technological parameters within the structure of cokes produced from binary and ternary coal blends: International Journal of Coal Geology, v. 111, p. 90-97.Sminchak, J., M. Gupta, and J. Gerst, 2009, Well test results and reservoir performance for a carbon dioxide injection test in the Bass Islands dolomite in the Michigan Basin: Environmental Geosciences, v. 16, no. 3, p. 153-162.Smistad, E., 2013, Environmental impacts in gas production monitored by NETL: World Oil, v. 234, no. 9, p. 119-122.

Smith, A.H.V., 1962, The paleoecology of Carboniferous peats based on the miospores and petrography of bituminous coals: Proceedings Yorkshire Geological Society, v. 33, p. 423-474.

Smith, D.M., and F.L. Williams, 1984, Diffusion models for gas production from coals – application to methane content determination: Fuel, v. 63, p. 251-255.Smith, D.M., and F.L. Williams, 1984, Diffusion models for gas production from coals – determination of diffusion parameters: Fuel, v. 63, p. 256-261.Smith, D.M., and F.L. Williams, 1984, Direct method of determining the ethane content of coal: a modification: Fuel, v. 63, p. 425-426.Smith, G.C., and A.C. Cook, 1980, Coalification paths of exinite, vitrinite and inertinite: Fuel, v. 59, p. 641-646.Smith, G.S., and A.C. Cook, 1980, Coalification paths of exinite, vitrinite, and inertinite: Fuel, v. 59, p. 641-646.Smith, H.D., and J.P. Messervey, 1952, Second conference on the origin and constitution of coal: Crystal Cliffs, Nova Scotia Department of Mines, 394 p.Smith, H.D., and J.P. Messervey, 1956, Third conference on the origin and constitution of coal: Crystal Cliffs, Nova Scotia Department of Mines, 386 p.Smith, J.D., T.T. Spence, P.J. Smith, A.U. Blackham, and L.D. Smoot, 1988, Effects of coal quality on utility furnace performance: Fuel, v. 67, p. 27-35.Smith, J.R., and J.W. Smith, 2007, A relationship between the carbon and hydrogen content of coals and their vitrinite reflectance: International Journal of Coal Geology, v. 70, p. 79-86.Smith, J.W. and R.J. Pallasser, 1996, Microbial origin of Australian coalbed methane: AAPG Bulletin, v. 80, p. 891-897.Smith, J.W., 1976, Oil shale and tar sands: New York, American Institute of Chemical Engineers, AIChE Symposium Series, v. 72, no. 155, 78 p.Smith, J.W., 1980, Oil shale resources of the United States: Golden, Colorado School of Mines Mineral and Energy Resources, v. 23, no. 6, 30 p.

Smith, J.W., and R.J. Pallasser, 2001, Comment on Boreham et al. (1998), "Factors controlling the origin of gas in Australian Bowen basin coals": Organic Geochemistry, v. 32, p. 205-206.Smith, J.W., D. Rigby, K.W. Gould, G. Hart, and A.J. Hargraves, 1985, An isotopic study of hydrocarbon generation processes: Organic Geochemistry, v. 8, p. 341-347.Smith, J.W., M. Ahmed, and D. Phan, 2001, Reactions accompanying loss of coking ability during the aerial oxidation of coal: Organic Geochemistry, v. 32, p. 1233-1240.Smith, J.W., M. Ahmed, and D. Phan, 2001, Reactions accompanying loss of coking ability during the aerial oxidation of coal: Organic Geochemistry, v. 32, p. 1233-1240.

Smoot, L.D., and P.J. Smith, 1985, Coal combustion and gasification: New York, Plenum Press, 443 p.Smoot, L.D., ed., 1992, Fundamentals of coal combustion: New York, Elsevier Science Publishers, Coal Science and Technology, v. 20, 750 p.Smyth, M., 1983, Nature of source material for hydrocarbons in Cooper basin, Australia: AAPG Bulletin, v. 67, p. 1422-1426.

Smyth, M., and M.J. Buckley, 1993, Statistical analysis of the microlithotype sequences in the Bulli seam, Australia, and relevance to permeability for coal gas: International Journal of Coal Geology, v. 22, p. 167-187.Smyth, M., and M.J. Buckley, 1993, Statistical analysis of the microlithotype sequences in the Bulli seam, Australia, and relevance to permeability for coal gas: International Journal of Coal Geology, v. 22, p. 167-187.Smyth, M., and M.J. Buckley, 1993, Statistical analysis of the microlithotype sequences in the Bulli seam, Australia, and relevance to permeability for coal gas: International Journal of Coal Geology, v. 22, p. 167-187.Snape, C., ed., Composition, geochemistry and conversion of oil shales: Boston, Kluwer Academic Publishers, NATO ASI Series C, Mathematical and Physical Sciences, v. 455, 505 p.Snape, C.E., 1987, Characterization of organic structure for liquefaction: Fuel Processing Technology, v. 15, p. 257-279.

Smith, A.C., and C.P. Lazzara, 1993, Spontaneous combustion during the storage and transport of coal, in S.-H. Chiang, ed., Coal — energy and the environment: Tenth Annual International Pittsburgh Coal Conference, Proceedings, p. 1009-1015.Smith, A.H.V., 1962, The palaeoecology of Carboniferous peats based on the miospores and petrography of bituminous coals, reprinted in M.D. Muir and W.A.S. Sarjeant, eds., Palynology, part I; Spores and pollen: Dowden, Hutchinson & Ross, Inc., Benchmark Papers in Geology, no. 46, p. 334-368.

Smith, A.H.V., 1968, Seam profiles and seam characters, in D.G. Murchison and T.S. Westoll, eds., Coal and coal-bearing strata: Edinburgh, Oliver and Boyd,p. 31-40.

Smith, J.W., 1999, The development of an understanding of the origins of the Sydney and Bowen basin gases, in M. Mastalerz, M. Glikson, and S.D. Golding, eds., Coalbed methane: scientific, environmental and economic evaluation: Boston, Kluwer Academic Publishers, p. 271-277.

Smith, P.M.R., 1983, Spectral correlation of spore coloration standards, in J. Brooks, ed., Petroleum geochemistry and exploration of Europe: Boston, Blackwell Scientific Publications, Geological Society Special Publication 12, p. 289-294.Smith, P.M.R., 1983, Spectral correlation of spore coloration standards, in J. Brooks, ed., Petroleum geochemistry and exploration of Europe: Boston, Blackwell Scientific Publications, p. 289-294.Smith, P.M.R., 1984, The use of fluorescence microscopy in the characterization of amorphous organic matter, in P.A. Schenck, J.W. de Leeuw, and G.W.M. Lijmbach, eds., Advances in organic geochemistry 1983: Organic Geochemistry, v. 6, p. 839-845.

Smyth, M., 1984, Coal microlithotypes related to sedimentary environments in the Cooper Basin, Australia, in R.A. Rahmani and R.M. Flores, eds., Sedimentology of coal and coal-bearing sequences: Boston, Blackwell Scientific Publications, International Association of Sedimentologists Special Publication 7, p. 333-347.Smyth, M., 1984, The relationship between coal macerals and microlithotypes in depositional environments, in B.G. Jones and A.C. Hutton, eds., Fluvio-deltaic systems: Facies analysis in exploration: Wollongong, Australian Sedimentology Specialist Group; Geological Society of Australia, p. 259-288.

Snape, C.E., 1991, Similarities and differences of coal reactivity in liquefaction and pyrolysis: Fuel, v. 70, p. 285.Snape, C.E., and C.J. Lafferty, 1990, Catalytic hydropyrolysis, a route to high oil yields from coal: Erdöl und Kohle-Erdgas-Petrochemie, v. 43, p. 342-343.

Snow, N., 2007, US House votes to delay oil shale leasing, development: Oil & Gas Journal, v. 105.26, p. 25.Snow, N., 2008, BLM finalizes oil shale regulations: Oil & Gas Journal, v. 106.44, p. 28-29.Snow, N., 2008, Oil shale debate becomes ‘chicken-or-the-egg’ question: Oil & Gas Journal, v. 106.20, p. 27-29.Snow, N., 2010, Studying CBM water: Oil & Gas Journal, v. 108.30, p. 29.

Snowdon, L.R., 1995, Rock-Eval Tmax suppression: documentation and amelioration: AAPG Bulletin, v. 79, p. 1337-1348.Snowdon, L.R., and T.G. Powell, 1982, Immature oil and condensate - modification of hydrocarbon generation model for terrestrial organic matter: AAPG Bulletin, v. 66, p. 775-788.

Snyder, R.E., 2004, Oil shale back in the picture: World Oil, v. 225, no. 8, p. 19.Snyder, R.E., 2005, North American coalbed methane development moves forward: World Oil, v. 226, no. 8, p. 57-59.Snyman, C.P., 1989, The role of coal petrography in understanding the properties of South African coal: International Journal of Coal Geology, v. 14, p. 83-101.

Soerensen, K.J., and N.W. Cant, 1988, The role of catalysis by mineral matter during oil shale retorting: Fuel, v. 67, p. 1344-1348.

Solano-Acosta, W., M. Mastalerz, and A. Schimmelmann, 2007, Cleats and their relation to geologic lineaments and coalbed methane potential in Pennsylvanian coals in Indiana: International Journal of Coal Geology, v. 72, p. 187-208.Solaymani, Z., and N. Taghipour, 2012, Petrographic characteristics and palaeoenvironmental setting of Upper Triassic Olang coal deposits in northeastern Iran: International Journal of Coal Geology, v. 92, p. 82-89.

Song, Y., S. Liu, F. Hong, L. Jiang, and X. Ma, 2013, Coalbed methane, chapter 4 in Unconventional petroleum geology: New York, Elsevier, p. 111-147.Sonibare, O.O., D.E. Jacob, C.R. Ward, and S.F. Foley, 2011, Mineral and trace element composition of the Lokpanta oil shales in the Lower Benue Trough, Nigeria: Fuel, v. 90, p. 2843-2849.

Sööt, P.M., 1991, Tax incentives spur development of coalbed methane: Oil & Gas Journal, v. 89, no. 23, p. 40-42.

Sorai, M., T. Ohsumi, M. Ishikawa, and K. Tsukamoto, 2007, Feldspar dissolution rates measured using phase-shift interferometry: Implications to CO2 underground sequestration: Applied Geochemistry, v. 22, p. 2795-2809.Sosrowidjojo, I.B., and A. Saghafi, 2009, Development of the first coal seam gas exploration program in Indonesia: Reservoir properties of the Muaraenim Formation, south Sumatra: International Journal of Coal Geology, v. 79, p. 145-156.Sotirov, A., and J. Kortenski, 2004, Petrography of the coal from the Oranovo-Simitli Basin, Bulgaria and indices of the coal facies: International Journal of Coal Geology, v. 57, p. 71-76.Southam, G., R. Donald, A. Röstad, and C. Brock, 2001, Pyrite discs in coal: evidence for fossilized bacterial colonies: Geology, v. 29, p. 47-50.Southam, G., R. Donald, A. Röstad, and C. Brock, 2001, Pyrite discs in coal: evidence for fossilized bacterial colonies: Geology, v. 29, p. 47-50.Spackman, W., 1958, The maceral concept and the study of modern environments as a means of understanding the nature of coal: Transactions New York Academy of Sciences, series II, v. 20, no. 5, p. 411-423.

Spackman, W., 2000, History of applied coal petrography in the United States, II. A personalized history of the origin and development of applied coal petrography at the Pennsylvania State University: International Journal of Coal Geology, v. 42, p. 103-114.Spackman, W., 2000, History of applied coal petrology in the United States. II. A personalized history of the origin and development of applied coal petrology at the Pennsylvania State University: International Journal of Coal Geology, v. 42, p. 103-114.Spackman, W., A. Davis, and G.D. Mitchell, 1976, The fluorescence of liptinite materials: Brigham Young University Geology Studies, v. 22, part 3, p. 59-75.Spackman, W., A.D. Cohen, P.H. Given, and D.J. Casagrande, 1974, A fieldguide to aid in the comparative study of the Okefenokee Swamp and Everglades-Mangrove Swamp-Marsh Complex of southern Florida: Geological Society of America preconvention field trip no. 6, 265 p.

Snape, C.E., F.J. Derbyshire, H.P. Stephens, R.J. Kottenstett, and N.W. Smith, 1991, Influence of organic coal structure on liquefaction behavior under low-severity conditions, in H.H. Schobert, K.D. Bartle, and L.J. Lynch, eds., Coal science II: Washington, D.C., American Chemical Society, Symposium Series 461, p. 182-192.

Snowdon, L.R., 1980, Resinite - a potential petroleum source in the Upper Cretaceous and Tertiary of the Beaufort-Mackenzie basin, in A.D. Miall, ed., Facts and principles of world petroleum occurrence: Canadian Society of Petroleum Geologists, Memoir 6, p. 509-520.Snowdon, L.R., 1991, Oil from type III organic matter: resinite revisited, in P.K. Mukhopadhyay, M.G. Fowler, and W.G. Dow, eds., Selected papers from the symposium on coal and terrestrial organic matter as a source rock for petroleum: Organic Geochemistry, v. 17, p. 743-747.

Snyder, G.T., W.C. Riese, S. Franks, U. Fehn, W.L. Pelzmann, A.W. Gorody, and J.E. Moran, 2003, Origin and history of waters associated with coalbed methane: 129I, 36Cl, and stable isotope results from the Fruitland Formation, CO and NM: Geochimica et Cosmochimica Acta, v. 67, p. 4529-4544.

Soeder, D.J., 1991, The effects of overburden stress on coalbed methane production, in D.C. Peters, ed., Geology in coal resource utilization: Fairfax, VA, Techbooks, p. 125-135.

Sokol, E.V., and N.I. Volkova, 2007, Combustion metamorphic events resulting from natural coal fires, in G.B. Stracher, ed., Geology of coal fires: case studies from around the world: GSA Reviews in Engineering Geology 18, p. 97-115.Solano-Acosta, W., A. Schimmelmann, M. Mastalerz, and I. Arango, 2008, Diagenetic mineralization in Pennsylvanian coals from Indiana, USA: 13C/12C and 18O/16O implications for cleat origin and coalbed methane generation: International Journal of Coal Geology, v. 73, p. 219-236.

Solomon, P.R., M.A. Serio, G.V. Deshpande, E. Kroo, H.H. Schobert, and C. Burgess, 1991, Chemistry of catalytic preliquefaction, in H.H. Schobert, K.D. Bartle, and L.J. Lynch, eds., Coal science II: Washington, D.C., American Chemical Society, Symposium Series 461, p. 193-212.

Sööt, P.M., 1988, Non-conventional fuel tax credit, in J.E. Fassett, ed., Geology and coal-bed methane resources of the northern San Juan basin, Colorado and New Mexico: Denver, Rocky Mountain Association of Geologists Guidebook, p. 253-255.

Sööt, P.M., 1991, Western United States coalbed methane gas content correlations, in S.D. Schwochow, D.K. Murray, and M.F. Fahy, eds., Coalbed methane of western North America: Denver, Rocky Mountain Association of Geologists, p. 87-92.

Spackman, W., 1989, Sample selection, in R. Klein and R. Wellek, eds., Sample selection, aging, and reactivity of coal: New York, John Wiley & Sons, p. 1-48.Spackman, W., 1989, Sample selection, in R. Klein and R. Wellek, eds., Sample selection, aging, and reactivity of coal: New York, John Wiley & Sons, p. 1-48.Spackman, W., 1989, Sample selection, in R. Klein and R. Wellek, eds., Sample selection, aging, and reactivity of coal: New York, John Wiley & Sons, p. 1-48.

Spackman, W., and E.S. Barghoorn, 1966, Coalification of woody tissue as deduced from a petrographic study of the Brandon lignite, in R.F. Gould, ed., Coal science: Washington, D.C., American Chemical Society, p. 695-707.

Spackman, W., and R. Thompson, 1964, A coal constituent classification designed to evolve as knowledge of coal composition evolves: Cinquieme Congres International de Stratigraphie de Geologie due Carbonifere, Paris, p. 239-253.Spackman, W., and R.G. Moses, 1961, The nature and occurrence of ash-forming minerals in anthracite: Proceedings 1960 Anthracite Conference, Penn State Min. Ind. Exp. Sta. Bull 75, p. 1-15.Spackman, W., C.P. Dolsen, and W. Riegel, 1966, Phytogenic organic sediments and sedimentary environments in the Everglades mangrove complex: Palaeontographica (Abt. B), v. 117, p. 135-152.Spackman, W., D.W. Scholl, and W.H. Taft, 1964, Environments of coal formation in southern Florida: Geological Society of America preconvention field guidebook, Miami University Institute of Marine Science Press, 67 p.Spackman, W., N.J. Ryan, C.A. Rhoads, and P.H. Given, 1988, Studies of peat as the input to coalification, II. Sampling sites and preliminary fractionation: International Journal of Coal Geology, v. 9, p. 253-265.

Sparks, D. P., S. W. Lambert, and T. H. McLendon, 1993, Coalbed gas well flow performance controls, Cedar Cove area, Warrior Basin, U.S.A.: Tuscaloosa, Alabama, University of Alabama, 1993 International Coalbed Methane Symposium Proceedings, p. 529-548.SPE, 1992, Coalbed methane: Society of Petroleum Engineers, Reprint Series 35, 237 p.

Spears, D.A., 2005, A review of chlorine and bromine in some United Kingdom coals: International Journal of Coal Geology, v. 64, p. 257-265.Spears, D.A., 2012, The origin of tonsteins, an overview, and links with seatearths, fireclays and fragmental clay rocks: International Journal of Coal Geology, v. 94, p. 22-31.Spears, D.A., 2012, The origin of tonsteins, an overview, and links with seatearths, fireclays and fragmental clay rocks: International Journal of Coal Geology, v. 94, p. 22-31.Spears, D.A., A.G. Borrego, A. Cox, and R.M. Martinez-Tarazona, 2007, Use of laser ablation ICP-MS to determine trace element distributions in coals, with special reference to V, Ge and Al: International Journal of Coal Geology, v. 72, p. 165-176.Spears, D.A., and M.R. Martinez-Tarazona, 1993, Geochemical and mineralogical characteristics of a power station feed-coal, Eggsborough, England: International Journal of Coal Geology, v. 22, p. 1-20.Spears, D.A., and M.R. Martinez-Tarazona, 1993, Geochemical and mineralogical characteristics of a power station feed-coal, Eggsborough, England: International Journal of Coal Geology, v. 22, p. 1-20.

Spears, D.A., and S.A. Caswell, 1986, Mineral matter in coals: cleat minerals and their origin in some coals from the English midlands: International Journal of Coal Geology, v. 6, p. 107-125.Spears, D.A., and S.A. Caswell, 1986, Mineral matter in coals: cleat minerals and their origin in some coals from the English midlands: International Journal of Coal Geology, v. 6, p. 107-125.Spears, D.A., and S.J. Tewalt, 2009, The geochemistry of environmentally important trace elements in UK coals, with special reference to the Parkgate coal in the Yorkshire-Nottinghamshire coalfield, UK: International Journal of Coal Geology, v. 80, p. 157-166.Spears, D.A., and Y. Zheng, 1999, Geochemistry and origin of elements in some UK coals: International Journal of Coal Geology, v. 38, p. 161-179.Spears, D.A., J.H. Rippon, and P.F. Cavender, 1999, Geological controls on the sulphur distribution in British Carboniferous coals: a review and reappraisal: International Journal of Coal Geology, v. 40, p. 59-81.Spears, D.A., M.R. Martinez Tarazona, and S. Lee, 1994, Pyrite in UK coals: its environmental significance: Fuel, v. 73, p. 1051-1055.

Spedding, P.J., 1988, Peat: Fuel, v. 67, p. 883-900.Speight, J.G., 1994, The chemistry and technology of coal (second edition): New York, Marcel Dekker Inc., 642 p.Speight, J.G., 2005, Handbook of coal analysis: Hoboken, New Jersey, John Wiley & Sons, Chemical Analysis Monograph v. 166, 222 p.Speight, J.G., 2005, Handbook of coal analysis: Hoboken, New Jersey, John Wiley & Sons, Chemical Analysis Monograph v. 166, 222 p. (mineral matter p. 92-109)Spiker, E.C., B.S. Pierce, A.L. Bates, and R.W. Stanton, 1994, Isotopic evidence for the source of sulfur in the upper Freeport coal bed (west-central Pennsylvania, U.S.A.): Chemical Geology, v. 114, p. 115-130.Spiro, B., and P.K. Mukhopadhyay, 1983, Effects of degradation on spectral fluorescence of alginate: Erdöl und Kohle-Erdgas-Petrochemie, v. 36, p. 297-299.Splettstoesser, J.F., 1980, Coal in Antarctica: Economic Geology, v. 75, p. 936-942.

Sprunk, G.C., 1942, Influence of physical constitution of coal upon its chemical, hydrogenation, and carbonization properties: Journal of Geology, v. 50, p. 411-436.Sprunk, G.C., and H.J. O’Donnell, 1942, Mineral matter in coal: U.S. Bureau of Mines, Technical Paper 648, 67 p.Sprunk, G.C., and R. Thiessen, 1935, Relation of microscopic composition of coal to chemical, coking, and by-product properties: Industrial and Engineering Chemistry, v. 27, p. 446-451.Sprunk, G.C., W.H. Ode, W.A. Selvig, and H.J. O’Donnell, 1940, Splint coals of the Appalachian region: their occurrence, petrography, and comparison of chemical and physical properties with associated bright coals: U.S. Bureau of Mines Technical Paper 615, 59 p.Squaret, J., and M. Dawson, 2006, Coalbed methane expands in Canada: Oil & Gas Journal, v. 104, no. 28, p. 37-50.Srivastava, R.M., 2013, Geostatistics: A toolkit for data analysis, spatial prediction and risk management in the coal industry: International Journal of Coal Geology, v. 112, p. 2-13.Stach, E., 1927, The origin of fusain: Fuel, v. 6, p. 403-410.Stach, E., 1949, The petrography of coal: Brit. Coal Utilis. Res. Assoc., Bulletin, v. 8, no. 6, p. 193-198.Stach, E., 1955, Crassidurain—a means of seam correlation in the Carboniferous coal measures of the Ruhr: Fuel, v. 34, p. 95-118.

Spackman, W., W.L. Riegel, and C.P. Dolsen, 1969, Geological and biological interactions in the swamp-marsh complex of southern Florida, in E.C. Dapples and M.E. Hopkins, eds., Environments of coal deposition: Geological Society of America, Special Paper 114, p. 1-35.

Spears, D.A., 1987, Mineral matter in coals, with special reference to the Pennine Coalfields, in A.C. Scott, ed., Coal and coal-bearing strata: recent advances: Boston, Blackwell Scientific Publications, Geological Society Special Publication 32, p. 171-185.Spears, D.A., 1987, Mineral matter in coals, with special reference to the Pennine coalfields, in A.C. Scott, ed., Coal and coal-bearing strata: recent advances: Geological Society Special Publication 32, p. 171-185.

Spears, D.A., and P.C. Lyons, 1995, An update on British tonsteins, in M.K.G. Whateley and D.A. Spears, eds., European coal geology: London, Geological Society Special Publication 82, p. 137-146.

Specht, R.W., 2001, Coalbed methane potential of the Williston Basin, North Dakota, in M.R. Silverman, ed., Emerging coalbed methane plays of North America: Denver, CO, Petroleum Frontiers, v. 18, no. 3, p. 40-50.

Sprigg, R.C., 1986, The Eromanga basin in the search for commercial hydrocarbons, in D.I. Gravestock, P.S. Moore, and G.M. Pitt, eds., Contributions to the geology and hydrocarbon potential of the Eromanga basin: Geological Society of Australia Special Publication 12, p. 9-24.

Stach, E., M.-Th. Mackowsky, M. Teichmüller, G.H. Taylor, D. Chandra, and R. Teichmüller, 1982, Stach’s textbook of coal petrology (third revised and enlarged edition): Berlin Stuttgart, Gebrüder Borntraeger, 535 p.Stach, E., M.-Th. Mackowsky, M. Teichmüller, G.H. Taylor, D. Chandra, and R. Teichmüller, 1982, Stach’s textbook of coal petrology (third revised and enlarged edition): Berlin Stuttgart, Gebrüder Borntraeger, 535 p.

Stach, E., M.-Th. Mackowsky, M. Teichmüller, G.H. Taylor, D. Chandra, and R. Teichmüller, 1982, Stach's textbook of coal petrology, third revised and enlarged edition: Berlin-Stuttgart, Gebrüder Borntraeger, 535 p. (see p. 319-329).Stadnichenko, T., and others, 1961, Berryllium content of American coals: U.S. Geological Survey Bulletin 1084K, p. 253-295.Staib, G., R. Sakurovs, and E.M.A. Gray, 2013, A pressure and concentration dependence of CO2 diffusion in two Australian bituminous coals: International Journal of Coal Geology, v. 116-117, p. 106-116. (enhanced coalbed methane)Stańczyk, K., K. Kapusta, M. Wiatowski, J. Świądrowski, A. Smoliński, J. Rogut, and A. Kotyrba, 2011, Experimental simulation of hard coal underground gasification for hydrogen production: Fuel, v. 91, p. 40-50.Stanfield, K.E., and C.I. Frost, 1946, Method of assaying oil shale by a modified Fischer retort: U.S. Bureau of Mines Report of Investigations 3977, 11 p.Stanfield, K.E., and C.I. Frost, 1949, Method of assaying oil shale by a modified Fischer retort: U.S. Bureau of Mines Report of Investigations 4477, 13 p.Stankiewicz, B.A., M. Mastalerz, M.P. Kruge, P.F. van Bergen, and A. Sadowska, 1997, A comparative study of recent and fossil cone scales and seeds of conifers: a geochemical approach: New Phytologist, v. 135, p. 375-393.Stankiewicz, B.A., M.A. Kruge, and J.C. Crelling, 1994, Geochemical characterization of maceral concentrates from Herrin No. 6 coal (Illinois Basin) and Lower Toarcian Shale kerogen (Paris Basin): Bulletin Des Centres De Recherches Exploration-Production, Special Publication 18, p. 237-251.Stankiewicz, B.A., M.A. Kruge, and M. Mastalerz, 1996, A study of constituent macerals of Miocene and Eocene coals from Indonesia: implications for the origin of aliphatic-rich vitrinite and resinite: Organic Geochemistry, v. 24, p. 531-545.Stankiewicz, B.A., M.A. Kruge, J.C. Crelling, and G.L. Salmon, 1994, Density gradient centrifugation: application to the separation of macerals of type I, II, and III sedimentary organic matter: Energy and Fuels, v. 8, p. 1513-1521.Stankova, A., N. Gilon, L. Dutruch, and V. Kanicky, 2010, A simple LIBS method for fast quantitative analysis of fly ashes: Fuel, v. 89, p. 3468-3474.Stannage, W., 1988, Some problems in petroleum geochemistry: Journal of Petroleum Geology, v. 11, p. 415-428.

Stanton, R.W., and T.A. Moore, 1991, Types of vitrinite macerals I: the necessity for etching: TSOP Newsletter, v. 8, no. 1, p. 8-11.Stanton, R.W., R.M. Flores, P.D. Warwick, and H.J. Gluskoter, 2002, Sequestration of carbon dioxide in low-rank coals (abstract): TSOP Abstracts and Program, v. 18, p. 111.Stanton, R.W., R.M. Flores, P.D. Warwick, and H.J. Gluskoter, 2002, Sequestration of carbon dioxide in low-rank coals (abstract): TSOP Abstracts and Program, v. 18, p. 111.

Staplin, F.L., 1969, Sedimentary organic matter, organic metamorphism and oil and gas occurrence: Bulletin of Canadian Petroleum Geology, v. 17, p. 47-66.Stasiuk, L.D., 1993, Algal bloom episodes and the formation of bituminite and micrinite in hydrocarbon source rocks: evidence from the Devonian and Mississippian, northern Williston Basin, Canada: International Journal of Coal Geology, v. 24, p. 195-210.Stasiuk, L.D., 1994, Fluorescence properties of Palaeozoic oil-prone alginate in relation to hydrocarbon generation, Williston Basin, Saskatchewan, Canada: Marine and Petroleum Geology, v. 11, p. 219-231.Stasiuk, L.D., 1994, Oil-prone alginite macerals from organic-rich Mesozoic and Palaeozoic strata, Saskatchewan, Canada: Marine and Petroleum Geology, v. 11, p. 208-218.Stasiuk, L.D., 1994, Petrographic thermal maturity assessment of Winnipegosis (Middle Devonian) and Bakken (Devonian-Mississippian) formations, southeastern Saskatchewan: Bulletin of Canadian Petroleum Geology, v. 42, p. 178-186.Stasiuk, L.D., 1997, The origin of pyrobitumens in Upper Devonian Leduc Formation gas reservoirs, Alberta, Canada: an optical and EDS study of oil to gas transformation: Marine and Petroleum Geology, v. 14, p. 915-929.

Stasiuk, L.D., 1999, Microscopic studies of sedimentary organic matter: key to understanding organic-rich strata, with Paleozoic examples from western Canada basin: Geoscience Canada, v. 26, p. 149-172.Stasiuk, L.D., and F. Goodarzi, 1988, Organic petrology of Second White Speckled Shale, Saskatchewan, Canada - a possible link between bituminite and biogenic gas?: Bulletin of Canadian Petroleum Geology, v. 36, p. 397-406.Stasiuk, L.D., and H. Sanei, 2001, Characterization of diatom-derived lipids and chlorophyll within Holocene laminites, Saanich Inlet, British Columbia, using conventional and laser scanning fluorescence microscopy: Organic Geochemistry, v. 32, p. 1417-1428.Stasiuk, L.D., and K.G. Osadetz, 1993, Thermal maturity, alginate-bitumen transformation, and hydrocarbon generation in Upper Ordovician source rocks, Saskatchewan, Canada: Energy Sources, v. 15, p. 205-237.

Stach, E., 1956, The value of an international nomenclature for coal petrography, in Third conference on the origin and constitution of coal: Crystal Cliffs, Nova Scotia Department of Mines, p. 172-189.Stach, E., 1968, Basic principles of coal petrology: macerals, microlithotypes and some effects of coalification, in D.G. Murchison and T.S. Westoll, eds., Coal and coal-bearing strata: Edinburgh, Oliver & Boyd, p. 3-17.Stach, E., 1968, Basic principles of coal petrology: macerals, microlithotypes and some effects of coalification, in D.G. Murchison and T.S. Westoll, es., Coal and coal-bearing strata: Edinburgh, Oliver and Boyd, p. 3-17.Stach, E., 1982, The microscopically recognizable constituents of coal, in Stach’s Textbook of Coal Petrology, 3rd ed.: Berlin, Gebruder Borntraeger, p. 87-218.Stach, E., M.-Th. Mackowsky, M. Teichmüller, G.H. Taylor, D. Chandra, and R. Teichmüller, 1982, Stach’s textbook of coal petrology (3 rd revised and enlarged edition): Berlin-Stuttgart, Gebrüder Borntraeger, 535 p.

Stach, E., M.-Th. Mackowsky, M. Teichmuller, G.H. Taylor, D. Chandra, and R. Teichmuller, 1982, Stach’s textbook of coal petrology, 3 rd edn: Berlin & Stuttgart, Gebruder Borntraeger, 535 p.

Stanton, R., R. Flores, P.D. Warwick, H. Gluskoter, and G.D. Stricker, 2001, Coal bed sequestration of carbon dioxide: National Energy Technology Laboratory First National Conference on Carbon Sequestration, 12 p. http://www.netl.doe.gov/publications/proceedings/01/carbon_seq/3a3.pdfStanton, R., R. Flores, P.D. Warwick, H. Gluskoter, and G.D. Stricker, 2001, Coal bed sequestration of carbon dioxide: National Energy Technology Laboratory, First National Conference on Carbon Sequestration, 12 p. http://www.netl.doe.gov/publications/proceedings/01/carbon_seq/3a3.pdfStanton, R.W., 1982, Application of fluorescence microscopy to the study of the components of coal, in K.F.J. Heinrich, ed., Microbeam analysis: San Francisco Press, Inc., p. 330-332.Stanton, R.W., 1982, Application of fluorescence microscopy to the study of the components of coal, in K.F.J. Heinrich, ed., Microbeam analysis—1982: San Francisco, San Francisco Press, Inc., p. 330-332.Stanton, R.W., 1989, Sampling of coal beds for analysis, in D.W. Golightly and F.O. Simon, eds., Methods for sampling and inorganic analysis of coal: U.S. Geological Survey Bulletin 1823, p. 7-13.Stanton, R.W., 1993, The role of petrography in coal characterization, in S.-H. Chiang, ed., Coal—energy and the environment: Tenth Annual International Pittsburgh Coal Conference, Proceedings, p. 295-297.

Stanton, R.W., T.A. Moore, P.D. Warwick, S.S. Crowley, and R.M. Flores, 1988, Styles of organic facies development in selected coal beds of the Powder River Basin: a petrographic evaluation, in G.S. Holden, ed., GSA Field Trip Guidebook: Colorado School of Mines, Professional Contributions 12, p. 195-204.

Stasiuk, L.D., 1999, Confocal laser scanning fluorescence microscopy of Botryococcus alginite from boghead oil shale, Boltysk, Ukraine: selective preservation of various micro-algal components: Organic Geochemistry, v. 30, p. 1021-1026.

Stasiuk, L.D., and K.G. Osadetz, 1993, Thermal maturity, alginite-bitumen transformation, and hydrocarbon generation in Upper Ordovician source rocks, Saskatchewan, Canada: Energy Sources, v. 15, p. 205-237.Stasiuk, L.D., and L.R. Snowdon, 1997, Fluorescence micro-spectrometry of synthetic and natural hydrocarbon fluid inclusions: crude oil chemistry, density and application of petroleum migration: Applied Geochemistry, v. 12, p. 229-241.Stasiuk, L.D., and M.G. Fowler, 1994, Paleozoic hydrocarbon source rocks, Truro Island, Arctic Canada: organic petrology, organic geochemistry and thermal maturity: Bulletin of Canadian Petroleum Geology, v. 42, p. 419-431.Stasiuk, L.D., F. Goodarzi, and H. Bagheri-Sadeghi, 2006, Petrology, rank and evidence for petroleum generation, Upper Triassic to Middle Jurassic coals, central Alborz Region northern Iran: International Journal of Coal Geology, v. 67, p. 249-258.

Stasiuk, L.D., P.D. Warwick, and E.M. Caddel, eds., 2006, Proceedings from coal bed methane—Back to the basics of coal geology: Bulletin of Canadian Petroleum Geology, v. 54, p. 195-297.Stasiuk, LD., and H. Sanei, 2001, Characterization of diatom-derived lipids and chlorophyll within Holocene laminites, Saanich Inlet, British Columbia, using conventional and laser scanning fluorescence microscopy: Organic Geochemistry, v. 32, p. 1417-1428.Staub, J.R., 1994, Mine level analysis of planar and raised peat deposition in a wave- and tide-influenced deltaic shoreline setting; Beckley bed (Westphalian A), southern West Virginia: Palaeogeography, Palaeoclimatology, Palaeoecology, v. 106, p. 203-221.Stayton, R.J., 2002, Horizontal wells boost CBM recovery: American Oil & Gas Reporter, v. 45, no. 8, p. 71-75.Stayton, R.J., 2005, Drilling technologies optimize development of unconventional plays: American Oil & Gas Reporter, v. 48, no. 9, p. 64-69.Stefanova, M., 2013, Molecular indicators of the Oligocene Bobov Dol coal organic matter composition from bitumen analysis and preparative off-line thermochemolysis: International Journal of Coal Geology, v. 118, p. 1-7.Stefanova, M., and B.R.T. Simoneit, 2008, Polar aromatic biomarkers of Miocene-aged Chukurovo resinite and correlation with a progenitor macrofossil: International Journal of Coal Geology, v. 75, p. 166-174.Stefanova, M., J. Kortenski, A. Zdravkov, and S. Marinov, 2013, Paleoenvironmental settings of the Sofia lignite basin: Insights from coal petrography and molecular indicators: International Journal of Coal Geology, v. 107, p. 45-61.Stegena, L., F. Horvath, J.G. Sclater, and L. Royden, 1981, Determination of paleotemperature by vitrinite reflectance data: Earth Evol. Sci., v. 1, p. 292-300.Steidl, P.F., 1978, Foam stimulation to enhance production from degasification wells in the Pittsburgh coalbed: U.S. Bureau of Mines, Report of Investigations 8286, 10 p.Steidl, P.F., 1991, Observations of induced fractures intercepted by mining in the Warrior basin, Alabama: Gas Research Institute, Topical Report, GRI-91/0327.Stell, J., 2007, Appalachian transfer: Oil and Gas Investor, v. 27, no. 12, p. 71-72.Stell, J., 2007, CO2 sequestration: Oil and Gas Investor, v. 27, no. 9, p. 13.Stell, J., 2009, U.S. gas supply, San Juan Basin revisited: Oil and Gas Investor, v. 29, no. 8, p. 81-83.Stell, S.M., 1986, The effects of cannel coal on coal and coke quality parameters and blast furnace ironmaking costs: Journal of Coal Quality, v. 5, no. 4, p. 126-130.Steller, M., 1987, Hydrogenation behavior of coal maceral association: International Journal of Coal Geology, v. 9, p. 109-127.

Steller, M., and W. Kalkreuth, 1990, Recent advances in the fluorescence microscopy of vitrinite and inertinite macerals: Erdöl und Kohle-Erdgas-Petrochemie, v. 43, p. 387-389.Steller, M., P. Arendt, and H. Kühl, 2006, Development of coal petrography applied in technical processes at the Bergbau-Forschung/DMT during the last 50 years: International Journal of Coal Geology, v. 67, p. 158-170.Steller, M., P. Arendt, and H. Kűhl, 2006, Development of coal petrography applied in technical processes at the Bergbau-Forschung/DMT during the last 50 years: International Journal of Coal Geology, v. 67, p. 158-170.Steller, M., W. Kalkreuth, and W. Hodek, 1987, Hydrogenation of selected subbituminous and bituminous coals; micropetrological and chemical studies on feedstock and reaction residues: Erdöl und Kohle-Erdgas-Petrochemie, v. 40, p. 383-393.Stenberg, E., and T. Doll, A review of the Powder River Basin coalbed methane play: The Mountain Geologist, v. 43, no. 3, p. 247-250.Stencel, J.M., 1990, Fluidized-bed combustion and energy production: Energeia, v. 1, no. 1, p. 2-4.Stephens, H.P., and R.J. Kottenstette, 1991, Studies of coal reactivity for direct liquefaction: Fuel, v. 70, p. 386.Stępniewska, Z., A. Pytlak, and A. Kuźniar, 2013, Methanotrophic activity in Carboniferous coalbed rocks: International Journal of Coal Geology, v. 106, p. 1-10. (secondary biogenic methane)Stępniewska, Z., A. Pytlak, and A. Kuźniar, 2014, Distribution of the methanotrophic bacteria in the western part of the Upper Silesian Coal Basin (Borynia-Zofiówa and Budryk coal mines): International Journal of Coal Geology, v. 130, p. 70-78.Stevens, S.H., B.S. Kelso, T.E. Lombardi, and J.-M. Coates, 1993, Raton basin assessment of coalbed methane resources: Quarterly Review of Methane from Coal Seams Technology, v. 10, no. 3, p. 7-13.Stevens, S.H., J.D. Nations, and S.L. Rauzi, 2002, Black Mesa coal basin, northeastern Arizona: an overlooked Rocky Mountain coalbed methane play (abstract): AAPG Annual Convention Official Program, v. 11, p. A168.Stevens, S.H., K. Sani, and S. Hardjosuwiryo, 2001, Indonesia’s 337 tcf CBM resource a low-cost alternative to gas, LNG: Oil & Gas Journal, v. 99, no. 43, p. 40-45.Stevens, S.H., T.E. Lombardi, B.S. Kelso, and J.M. Coates, 1992, A geologic assessment of natural gas from coal seams in the Raton and Vermejo Formations, Raton Basin: Gas Research Institute, Topical Report GRI 92/0345, 84 p.Stevens, S.H., V.A. Kuuskraa, J.J. Gale, and D. Beecy, 2000, CO2 injection and sequestration in depleted oil and gas fields and deep coal seams; worldwide potential and costs: AAPG Bulletin, v. 84, p. 1497-1498.Stewart, A.K., M. Massey, P.L. Padgett, S.M. Rimmer, and J.C. Hower, 2005, Influence of a basic intrusion on the vitrinite reflectance and chemistry of the Springfield (No. 5) coal, Harrisburg, Illinois: International Journal of Coal Geology, v. 63, p. 58-67.

Stiegel, G.J., and M. Ramezan, 2006, Hydrogen from coal gasification: an economical pathway to a sustainable energy future: International Journal of Coal Geology, v. 65, p. 173-190.

Stasiuk, L.D., F. Goodarzi, and M.G. Fowler, 1994, Corpohuminite from Canadian Paleozoic source rocks: petrology and reflectance properties, in P.K. Mukhopadhyay and W.G. Dow, eds., Vitrinite reflectance as a maturity parameter: applications and limitations: Washington, D.C., American Chemical Society Symposium Series 570, p. 52-63.Stasiuk, L.D., K.G. Osadetz, and J. Potter, 1990, Fluorescence spectral analysis and hydrocarbon exploration: examples from Paleozoic potential source rocks, Saskatchewan, in L.S. Beck and C.T. Harper, eds., Modern exploration techniques: Saskatchewan Geological Society, Special Publication 10, p. 242-251.

Steller, M., 1987, The influence of maceral intergrowth on the hydrogenation of coal, in 1987 International Conference on Coal Science: New York, Elsevier Science Publishers, p. 115-118.

Stewart, B.R., 1999, Coal combustion product (CCP) production and use: survey results, in K.S. Sajwan, A.K. Alva, and R.F. Keefer, eds., Biogeochemistry of trace elements in coal and coal combustion byproducts: New York, Kluwer Academic/Plenum Publishers, p. 1-6.

Stock, L.M., and R. Wolny, 1990, Elemental sulfur in bituminous coals, in W.L. Orr and C.M. White, eds., Geochemistry of sulfur in fossil fuels: Washington, D.C., American Chemical Society Symposium Series 429, p. 241-248.

Stoeckinger, B.T., 1989, Coal-bed methane production in eastern Kansas: its potential and restraints (abstract): AAPG Bulletin, v. 73, p. 1051.Stoeckinger, W.T., 1989, Methane from coal in southeast Kansas: the rebirth of an old industry: Proceedings of the 1989 Coalbed Methane Symposium, paper 8964, p. 211-224.Stoeckinger, W.T., 1990, Coal gas blooms in southeast Kansas: Oil News Service, Eastern Kansas Edition, v. 44, issue 187, 2 p. (originally printed in American Oil & Gas Reporter, v. 33, no. 9)Stoeckinger, W.T., 1990, Coalbed methane comes on stream: Kansas Geological Society, Bulletin, v. 66, no. 2, p. 8-12.Stoeckinger, W.T., 1990, Kansas coalbed methane comes on stream: Oil & Gas Journal, v. 88, no. 23, p. 88-90.

Stoeckinger, W.T., 1992, Coalbed methane production base established in southeast Kansas: Oil & Gas Journal, v. 90, no. 15, p. 90-91.Stojanović, K., and D. Životić, 2013, Comparative study of Serbian Miocene coals—Insights from biomarker composition: International Journal of Coal Geology, v. 107, p. 3-23.Stone, I.J., and A.C. Cook, 1979, The influence of some tectonic structures upon vitrinite reflectance: Journal of Geology, v. 87, p. 497-508.Stopes, M.C., 1919, On the four visible ingredients in banded bituminous coals: Proc. Roy. Soc., Ser. B, v. 90, p. 470-487.Stopes, M.C., 1935, On the petrology of banded bituminous coal: Fuel, v. 14, p. 4-13.Stopes, M.C., and D.M.S. Watson, 1909, On the present distribution and origin of the calcareous concretions in coal seams, known as "coal balls": Philosophical Transactions of the Royal Society of London, v. B200, p. 167-218.Stott, J., 2001, Canadian coalbed methane activity intensifies: Oil & Gas Journal, v. 99, no. 47, p. 37.Stout, S.A., 1993, Lasers in organic petrology and organic geochemistry, II. In-situ laser micropyrolysis—GCMS of coal macerals: International Journal of Coal Geology, v. 24, p. 309-331.

Stout, S.A., and D.F. Bensley, 1987, Fluorescing macerals from wood precursors: International Journal of Coal Geology, v. 7, p. 119-133.Stout, S.A., and R. Lin, 1992, Lasers in organic petrology and organic geochemistry—1. Laser-induced fluorescence, thermal extraction, and pyrolysis: Organic Geochemistry, v. 18, p. 229-239.Stout, S.A., and W. Spackman, 1987, A microscopic investigation of woody tissues in peats: some processes active in the peatification of lingo-cellulose cell walls: International Journal of Coal Geology, v. 8, p. 55-68.Stout, S.A., and W. Spackman, 1989, Notes on the compaction of a Florida peat and the Brandon lignite as deduced from the study of compressed wood: International Journal of Coal Geology, v. 11, p. 247-256.Stout, S.A., and W. Spackman, 1989, Peatification and early coalification of wood as deduced by quantitative microscopic methods: Organic Geochemistry, v. 14, p. 285-298.Stout, S.A., J.J. Boon, and W. Spackman, 1988, Molecular aspects of the peatification and early coalification of angiosperm and gymnosperm woods: Geochimica et Cosmochimica Acta, v. 52, p. 405-414.Stout, S.A., W. Spackman, J.J. Boon, P.G. Kistemaker, and D.F. Bensley, 1989, Correlations between the microscopic and chemical changes in wood during peatification and early coalification: a canonical variant study: International Journal of Coal Geology, v. 13, p. 41-64.Stracher G.B., A. Prakash, and E.V. Sokol, eds., 2010, Coal and peat fires: a global perspective; v. 1, coal – geology and combustion: New York, Elsevier Scientific Publ. Co., 380 p.Stracher G.B., A. Prakash, and E.V. Sokol, eds., 2012, Coal and peat fires: a global perspective; v. 2, photographs and multimedia tours: New York, Elsevier Scientific Publ. Co., 584 p.Stracher, G.B., 2007, Coal fires burning around the world: Opportunity for innovative and interdisciplinary research: GSA Today, v. 17, no. 11, p. 36-37.Stracher, G.B., 2010, The rising global interest in coal fires: Earth, v. 55, no. 9, p. 46-55.Stracher, G.B., ed., 2004, Coal fires burning around the World: a global catastrophe: International Journal of Coal Geology, Special Issue, v. 59, p. 1-151.Stracher, G.B., ed., 2007, Geology of coal fires: case studies from around the world: GSA Reviews in Engineering Geology 18, 283 p.Stranges, A.N., 2001, Germany’s synthetic fuel industry 1927-1945: University of Kentucky, Center for Applied Energy Research, Energeia, v. 12, no. 5, p. 1-2, 6. (history of liquefaction)Strąpoć D, M. Mastalerz, K. Dawson, J. Macalady, A.V. Callaghan, B. Wawrik, C. Turich, and M. Ashby, 2011, Biogeochemistry of microbial coal-bed methane: Annual Review of Earth and Planetary Sciences, v. 39, p. 617-656. Strąpoć, D., A. Schimmelmann, and M. Mastalerz, 2006, Carbon isotopic fractionation of CH4 and CO2 during canister desorption of coal: Organic Geochemistry, v. 37, p. 152-164.Strąpoć, D., F.W. Picardal, C. Turich, I. Schaperdoth, J.L. Macalady, J.S. Lipp, Y.S. Lin, T.F. Ertefai, F. Schubotz, K.U. Hinrichs, M. Mastalerz, and A. Schimmelmann, 2008, Methane-producing microbial community in a coal bed of the Illinois Basin: Applied and Environmental Microbiology, v. 74, p. 2424-2432. Strąpoć, D., M. Mastalerz, A. Schimmelmann, A. Drobniak, and S. Hedges, 2008, Variability of geochemical properties in a microbially dominated coalbed gas system from the eastern margin of the Illinois Basin, USA: International Journal of Coal Geology, v. 76, p. 98-110.Strąpoć, D., M. Mastalerz, C. Eble, and A. Schimmelmann, 2007, Characterization of the origin of coalbed gases in southeastern Illinois Basin by compound-specific carbon and hydrogen stable isotope ratios: Organic Geochemistry, v. 38, p. 267-287.

Strehlau, K., 1990, Facies and genesis of Carboniferous coal seams of northwest Germany: International Journal of Coal Geology, v. 15, p. 245-292.Stuhec, S., compiler, 1990, Introduction to coal sampling techniques for the petroleum industry: Alberta Research Council, Coal Bed Methane Seminar Series, Information Series 11, 223 p.Stukalova, I.E., and O.V. Rusinova, 2007, Thermal alteration of coal in the Khasyn coalfield, Magadan region, Russia: International Journal of Coal Geology, v. 71, p. 462-470.

Stutz, L., and K. Fisher, 2004, Fracture mapping and modeling optimize CBM fracture treatments: World Oil, v. 225, no. 6, p. 63-64.Stutzer, O., and A.C. Noé, 1940, Geology of coal: Chicago, Illinois, University of Chicago Press, 461 p.

Stoeckinger, W.T., 1991, Methods to measure directly the gas content of coals, in Midcontinent core workshop, integrated studies of petroleum reservoirs in the Midcontinent: Kansas Geological Survey Open-File Report 91-52, p. 111-124.

Stout, S.A., 1994, Chemical heterogeneity among adjacent coal microlithotypes - implications for oil generation and primary migration from humic coal, in A.C. Scott and A.J. Fleet, eds., Coal and coal-bearing strata as oil-prone source rocks?: London, The Geological Society Special Publication 77, p. 93-106.

Straszheim, W.E., and R. Markuszewski, 1991, Advances in quantitative assessment of the association of mineral matter with coal, in H.H. Schobert, K.D. Bartle, and L.J. Lynch, eds., Coal science II: Washington, D.C., American Chemical Society, ACS Symposium Series 461, p. 31-43.

Stultz, S.C., 2005, Steam: its generation and use: Babcock and Wilcox Company, 41 st edition, 1064 p.

Styan, W.B., and R.M. Bustin, 1983, Petrography of some Fraser River Delta peat deposits: coal maceral and microlithotype precursors in temperate-climate peats: International Journal of Coal Geology, v. 2, p. 321-370.Styan, W.B., and R.M. Bustin, 1983, Sedimentology of Fraser River Delta peat deposits: a modern analogue for some deltaic coals: International Journal of Coal Geology, v. 3, p. 101-143.

Su, X., L. Zhang, and R. Zhang, 2003, The abnormal pressure regime of the Pennsylvanian No. 8 coalbed methane reservoir in Liulin–Wupu District, eastern Ordos Basin, China: International Journal of Coal Geology, v. 53, p. 227-239.Su, X., X. Lin, M. Zhao, Y. Song, and S. Liu, 2005, The upper Paleozoic coalbed methane system in the Qinshui Basin, China: AAPG Bulletin, v. 89, p. 81-100.Su, X., X. Lin, S. Liu, M. Zhao, and Y. Song, 2005, Geology of coalbed methane reservoirs in the southeast Qinshui Basin of China: International Journal of Coal Geology, v. 62, p. 197-210. (shear fracture permeability in anthracite)Su, X., Y. Feng, J. Chen, and J. Pan, 2001, The annealing mechanisms of cleats in coal: Tuscaloosa, Alabama, Proceedings, International Coalbed Methane Symposium, Paper 130, p. 351-356.Su, X., Y. Feng, J. Chen, and J. Pan, 2001, The characteristics and origins of cleat in coal from western North China: International Journal of Coal Geology, v. 47, p. 51-62.Suárez-Ruiz, I., 2004, Summary of the activities developed by the Coal Blends Working Group: ICCP News, No. 32, p. 14-21.Suárez-Ruiz, I., A. Jiménez, M.J. Iglesias, F. Laggoun-Defarge, and J.G. Prado, 1994, Influence of resinite on huminite properties: Energy & Fuels, v. 8, p. 1417-1424.Suárez-Ruiz, I., and A. Miménez, 2004, Coal facies studies in Spain: International Journal of Coal Geology, v. 58, p. 31-39.

Suárez-Ruiz, I., and J.C. Crelling, eds., 2008, Applied coal petrology: the role of petrology in coal utilization: New York, Academic Press, 388 p.Suárez-Ruiz, I., D. Flores, J. Graciano Mendonça Filho, and P.C. Hackley, 2012, Review and update of the applications of organic petrology: Part 1, geological applications: International Journal of Coal Geology, v. 99, p. 54-112.Suárez-Ruiz, I., D. Flores, J. Graciano Mendonça Filho, and P.C. Hackley, 2012, Review and update of the applications of organic petrology: Part 1, geological applications: International Journal of Coal Geology, v. 99, p. 54-112.Suárez-Ruiz, I., D. Flores, J. Graciano Mendonça Filho, and P.C. Hackley, 2012, Review and update of the applications of organic petrology: Part 2, geological and multidisciplinary applications: International Journal of Coal Geology, v. 98, p. 73-94.Suárez-Ruiz, I., D. Flores, J. Graciano Mendonça Filho, and P.C. Hackley, 2012, Review and update of the applications of organic petrology: Part 2, geological and multidisciplinary applications: International Journal of Coal Geology, v. 98, p. 73-94.Suárez-Ruiz, I., D. Flores, J. Graciano Mendonça Filho, and P.C. Hackley, 2012, Review and update of the applications of organic petrology: Part 2, geological and multidisciplinary applications: International Journal of Coal Geology, v. 98, p. 73-94. (spontaneous combustion)

Suau, J., 1981, Logging methods for coal exploration: Bulletin Des Centres De Recherchese Exploration-Production Elf-Aquitaine, v. 5, no. 2, p. 621-633.Subasinghe, N.D., F. Awaja, and S.K. Bhargava, 2008, Variation of kerogen content and mineralogy in some Australian tertiary oil shales: Fuel, v. 88, p. 335-339.Suchý, V., I. Sýkorová, M. Stejskal, J. Šafanda, V. Machovič, and M. Novotná, 2002, Dispersed organic matter from Silurian shales of the Barrandian Basin, Czech Republic: optical properties, chemical composition and thermal maturity: International Journal of Coal Geology, v. 53, p. 1-25.Suchý, V., P. Dobeš, L. Sýkorová, V. Machovič, M. Stejskal, J. Kroufek, J. Chudoba, L. Matějovský, M. Havelcová, and P. Matysová, 2010, Oil-bearing inclusions in vein quartz and calcite and bitumens in veins: Testament to multiple phases of hydrocarbon migration in the Barrandian basin (lower Palaeozoic), Czech Republic: Marine and Petroleum Geology, v. 27, p. 285-297.Suess, M.P., G. Drozdzewski, and A. Schaefer, 2007, Sedimentary environment dynamics and the formation of coal in the Pennsylvanian Variscan foreland in the Ruhr Basin (Germany, western Europe): International Journal of Coal Geology, v. 69, p. 267-287.

Suggate, R.P., 1974, Coal ranks in relation to depth and temperature in Australian and New Zealand oil and gas wells: New Zealand Journal of Geology and Geophysics, v. 17, p. 149-167.Suggate, R.P., 1998, Analytical variation in Australian coals related to coal type and rank: International Journal of Coal Geology, v. 37, p. 179-206.Suggate, R.P., 2000, The Rank(Sr) scale: its basis and its applicability as a maturity index for all coals: New Zealand Journal of Geology & Geophysics, v. 43, p. 521-553.Suggate, R.P., 2002, Application of Rank(Sr), a maturity index based on chemical analyses of coals: Marine and Petroleum Geology, v. 19, p. 929-950.Suggate, R.P., and J. P. Boudou, 1993, Coal rank and type variation in Rock-Eval assessment of New Zealand coals: Journal of Petroleum Geology, v. 16, p. 73-88.Suggate, R.P., and J.H. Lowery, 1982, The influence of moisture content on vitrinite reflectance and the assessment of maturation of coal: New Zealand Journal of Geology and Geophysics, v. 25, p. 227-231.Suggate, R.P., and J.P. Boudou, 1993, Coal rank and type variation in Rock-Eval assessment of New Zealand coals: Journal of Petroleum Geology, v. 16, p. 73-88.Suggate, R.P., and J.P. Boudou, 1996, Revision of the Mahakam coal series: Rock-Eval and rank(s) relations: Journal of Petroleum Geology, v. 19, p. 407-423.Suggate, R.P., and J.P. Boudou, 1996, Revision of the Mahakam coal series: Rock-Eval and Rank(s) relations: Journal of Petroleum Geology, v. 19, p. 407-423.Suggate, R.P., and W.W. Dickinson, 2004, Carbon NMR of coals: the effects of coal type and rank: International Journal of Coal Geology, v. 57, p. 1-22.Suggate, R.P., and W.W. Dickinson, 2004, Carbon NMR of coals: the effects of coal type and rank: International Journal of Coal Geology, v. 57, p. 1-22.Sun, P., R.F. Sachsenhofer, Z. Liu, S.A.I. Strobl, Q. Meng, R. Liu, and Z. Zhen, 2013, Organic matter accumulation in the oil shale- and coal-bearing Huadian Basin (Eocene; NE China): International Journal of Coal Geology, v. 105, p. 1-15.

Styan, W.B., and R.M. Bustin, 1984, Sedimentology of Fraser River Delta peat deposits: a modern analogue for some deltaic coals, in R.A. Rahmani and R.M. Flores, eds., Sedimentology of coal and coal-bearing sequences: Boston, Blackwell Scientific Publications, International Association of Sedimentologists Special Publication 7, p. 241-271.

Suárez-Ruiz, I., and C.R. Ward, 2008, Basic factors controlling coal quality and technological behavior of coal, in I. Suárez-Ruiz and J.C. Crelling, eds., Applied coal petrology: the role of petrology in coal utilization: New York, Academic Press, p. 19-59.Suárez-Ruiz, I., and C.R. Ward, 2008, Basic factors controlling coal quality and technological behavior of coal, in I. Suárez-Ruiz and J.C. Crelling, eds., Applied coal petrology: the role of petrology in coal utilization: New York, Academic Press, p. 19-59.Suárez-Ruiz, I., and C.R. Ward, 2008, Basic factors controlling coal quality and technological behavior of coal, in I. Suárez-Ruiz and J.C. Crelling, eds., Applied coal petrology: the role of petrology in coal utilization: New York, Academic Press, p. 19-59.Suárez-Ruiz, I., and C.R. Ward, 2008, Coal combustion, in I. Suárez-Ruiz and J.C. Crelling, eds., Applied coal petrology: the role of petrology in coal utilization: New York, Academic Press, p. 85-117.Suárez-Ruiz, I., and J.C. Crelling, 2008, Coal-derived carbon materials, in I. Suárez-Ruiz and J.C. Crelling, eds., Applied coal petrology: the role of petrology in coal utilization: New York, Academic Press, p. 193-225.

Suárez-Ruiz, I., M.J. Iglesias, A. Jiménez, F. Laggoun-Défarge, and J.G. Prado, 1994, Petrographic and geochemical anomalies detected in Spanish Jurassic jet, in P.K. Mukhopadhyay and W.G. Dow, eds., Vitrinite reflectance as a maturity parameter: applications and limitations: Washington, D.C., America Chemical Society, Symposium Series 570, p. 76-92.

Suggate, R., R.P. Suggate, and P.R. King, 1992, Timing and depth of maturation in southern Taranaki basin from reflectance and rank(s), in 1991 New Zealand oil exploration conference proceedings, v. 2: Wellington, The Publicity Unit, Crown Minerals Operations Group, Energy and Resources Division, Ministry of Commerce, p. 373-389.

Sun, Q., W. Li, H. Chen, and B. Li, 2003, The variation of structural characteristics of macerals during pyrolysis: Fuel, v. 82, p. 669-676.Sun, R., G. Liu, L. Zheng, and C.-L. Chou, 2010, Geochemistry of trace elements in coals from the Zhuji mine, Huainan Coalfield, Anjui, China: International Journal of Coal Geology, v. 81, p. 81-96.

Sun, X., 2002, The optical features and hydrocarbon-generating model of "barkinite" from Late Permian coals in south China: International Journal of Coal Geology, v. 51, p. 251-261.Sun, Y., 2003, Petrologic and geochemical characteristics of "barkinite" from the Dahe mine, Guizhou Province, China: International Journal of Coal Geology, v. 56, p. 269-276.Sun, Y., G. Sheng, P. Peng, and J. Fu, 2000, Compound-specific analysis as a tool for correlating coal-sourced oils and interbedded shale-sourced oils in coal measures: an example from Turpan Basin: Organic Geochemistry, v. 31, p. 1349-1362.Sun, Y., S. Qin, C. Zhao, Y. Li, H. Yu, and Y. Zhang, 2013, Organic geochemistry of semianthracite from the Gequan mine, Xingtai coalfield, China: International Journal of Coal Geology, v. 116-117, p. 281-292.Sun, Y.-Z., 1998, Influence of secondary oxidation and sulfide formation on several maturity parameters in Kupferschiefer: Organic Geochemistry, v. 29, p. 1419-1429.

Susilawati, R., and C.R. Ward, 2006, Metamorphism of mineral matter in coal from the Bukit Asam deposit, south Sumatra, Indonesia: International Journal of Coal Geology, v. 68, p. 171-195.Sutcu, E.C., 2012, Use of GIS to discover potential coalfields in Yatagan-Milas area in Turkey: International Journal of Coal Geology, v. 98, p. 95-109.Sutherland, J.K., 1975, Determination of organic sulphur in coal by microprobe: Fuel, v. 54, p. 132-134.Suziki, N., 1984, Characteristics of amorphous kerogens fractionated from terrigenous sedimentary rocks: Geochimica et Cosmochimica Acta, v. 48, p. 243-249.Suzuki, N., H. Matsubayashi, and D.W. Waples, 1993, A simpler kinetic model of vitrinite reflectance: AAPG Bulletin, v. 77, p. 1502-1508.Švábová, M., Z. Weishauptová, and O. Přibyl, 2012, The effect of moisture on the sorption process of CO2 on coal: Fuel, v. 92, p. 187-196.Švábová, M., Z. Weishauptová, and O. Přibyl, 2012, The effect of moisture on the sorption process of CO2 on coal: Fuel, v. 92, p. 187-196. (enhanced CBM)Svenster, P.G., 1959, Diffusion of gases through coal: Fuel, v. 38, p. 403-418.

Swaine, D.J., 1990, Trace elements in coal: North Ryde, Australia, Butterworths Pty Ltd., 296 p.Swaine, D.J., 1992, The organic association of elements in coals: Organic Geochemistry, v. 18, p. 259-261.Swaine, D.J., 1992, The organic association of elements in coals: Organic Geochemistry, v. 18, p. 259-261.Swaine, D.J., 1996, Trace elements in coal science: Journal and Proceedings, Royal Society of New South Wales, v. 129, p. 139-148.Swaine, D.J., 2000, Why trace elements are important: Fuel Processing Technology, v. 65-66, p. 21-33.Swaine, D.J., and F. Goodarzi, 1997, Environmental aspects of trace elements in coal: Dordrecht, Kluwer Academic Publishers, 312 p.Swanepoel, J.C., and C.A. Strydom, 2002, Utilisation of fly ash in a geopolymeric material: Applied Geochemistry, v. 17, p. 1143-1148.Swann, P.D., and D.G. Evans, 1979, Low-temperature oxidation of brown coal. 3. Reaction with molecular oxygen at temperatures close to ambient: Fuel, v. 58, p. 276-280.Swanson, S.M., M.A. Engle, L.F. Ruppert, R.H. Affolter, and K.B. Jones, 2013, Partitioning of selected trace elements in coal combustion products from two coal-burning power plants in the United States: International Journal of Coal Geology, v. 113, p. 116-126.Swanson, V.E., and C. Huffman, Jr., 1976, Guidelines for sample collecting and analytical methods used in the U.S. Geological Survey for determining chemical composition of coal: U.S. Geological Survey Circular 735, 11 p.Sweatman, R., and G.R. McColpin, 2009, Monitoring technology enables long-term CO2 geosequestration: Hart’s E&P, v. 82, no. 11, p. 72-73.Sweatman, R.E., M.E. Parker, and S.L. Crookshank, 2009, Industry CO2 EOR experience relevant for carbon capture and storage (CCS): Oil & Gas Journal, v. 107.45, p. 20-25.Sweeney, I.J., K. Chin, J.C. Hower, D.A. Budd, and D.G. Wolfe, 2009, Fossil wood from the middle Cretaceous Moreno Hill Formation: Unique expressions of wood mineralization and implications for the processes of wood preservation: International Journal of Coal Geology, v. 79, p. 1-17.Sweeney, J.J., and A.K. Burnham, 1990, Evaluation of a simple model of vitrinite reflectance based on chemical kinetics: AAPG Bulletin, v. 74, p. 1559-1570.Swift, A.M., L.M. Anovitz, J.M. Sheets, D.R. Cole, S.A. Welch, and G. Rother, 2014, Relationship between mineralogy and porosity in seals relevant to geologic CO2 sequestration: Environmental Geosciences Journal, v. 21, no. 2.

Sykes, R., 2004, Peat biomass and early diagenetic controls on the paraffinic oil potential of humic coals, Canterbury Basin, New Zealand: Petroleum Geosciences, v. 10, p. 283-303.Sykes, R., and J.K. Lindqvist, 1993, Diagenetic quartz and amorphous silica in New Zealand coals: Organic Geochemistry, v. 20, p. 855-866.Sykes, R., and K.C. Pratt, 1994, A simple and effective method for portraying and quantifying the macropetrography of lignites: a new tool for coal seam facies analysis: Journal of Sedimentary Research, v. A64, p. 699-701.Sykes, R., and L.R. Snowdon, 2002, Guidelines for assessing the petroleum potential of coaly source rocks using Rock-Eval pyrolysis: Organic Geochemistry, v. 33, p. 1441-1455.Sykes, R., and L.R. Snowdon, 2002, Guidelines for assessing the petroleum potential of coaly source rocks using Rock-Eval pyrolysis: Organic Geochemistry, v. 33, p. 1441-1455.Sykes, R., H. Volk, S.C. George, M. Ahmed, K.E. Higgs, P.E. Johansen, and L.R. Snowdon, 2014, Marine influence helps preserve the oil potential of coaly source rocks: Eocene Mangahewa Formation, Taranaki Basin, New Zealand: Organic Geochemistry, v. 66, p. 140-163.

Sun, S.Z., Y. Sun, C. Sun, Z. Liu, and N. Dong, 2014, Methods of calculating Total Organic Carbon from well logs and its application on rock’s properties analysis: AAPG Search and Discovery Article #41372, 12 p. http://www.searchanddiscovery.com/documents/2014/41372sun/ndx_sun.pdf

Sundquist, E.T., R.C. Burruss, S.P. Faulkner, R.A. Gleason, J.W. Harden, Y.K. Kharaka, L.L. Tieszen, and M.P. Waldrop, 2008, Carbon sequestration to mitigate climate change: U.S. Geological Survey, Fact Sheet 2008-3097, 4 p. http://pubs.usgs.gov/fs/2008/3097/Supardi, A.D. Subekty, and S.G. Neuzil, 1993, General geology and peat resources of the Siak Kanan and Bengkalis Island peat deposits, Sumatra, Indonesia, in J.C. Cobb and C.B. Cecil, eds., Modern and ancient coal-forming environments: Geological Society of America Special Paper 286, p. 45-61.

Swaine, D.J., 1983, Geological aspects of trace elements in coal, in S.S. Augustithis, ed., The significance of trace elements in solving petrogenetic problems and controversies: Athens, Greece, Theophrastus Publications S.A., p. 521-532.

Sykes, R., 2001, Depositional and rank controls on the petroleum potential of coaly source rocks, in K.C. Hill and T. Bernecker, eds., Eastern Australasian basins symposium, a refocused energy perspective for the future: Petroleum Exploration Society of Australia, Special Publication, p. 591-601.

Sykes, R., L.R. Snowdon, and R.H. Funnell, 2002, Improved evaluation of oil and gas generation and expulsion from coaly source rocks using Rock-Eval-based maturation pathways (abstract): TSOP Annual Meeting, abstract B3.2.2.Sykes, R., M.G. Fowler, and K.C. Pratt, 1994, A plant tissue origin for Ulminites A and B in Saskatchewan lignites and implications for Ro: Energy & Fuels, v. 8, p. 1402-1416.Sýkorová, I., V. Suchý, V. Melka, J. Šafanda, V. Machovič, and P. Dobeš, 2000, Petrology and chemistry of organic matter from Silurian shales in the Barrandian basin (abstract): TSOP Abstracts and Program, v. 17, p. 94-96.Sýkorová, I., W. Pickel, K. Christanis, M. Wolf, G.H. Taylor, and D. Flores, 2005, Classification of huminite—ICCP System 1994: International Journal of Coal Geology, v. 62, p. 85-106.Tabet, D.E., 2005, Deep Utah coal deposits—repositories for greenhouse gas emissions?: Utah Geological Survey, Survey Notes, v. 37, no. 1, p. 10-11.Tabet, D.E., and J.C. Quick, 2003, Frontier areas for coalbed-gas exploration in Utah: Utah Geological Survey, Survey Notes, v. 35, no. 2, p. 10-11.Tadmore, J., 1986, Radioactivity from coal-fired power plants: a review: Journal of Environmental Radioactivity, v. 4, p. 177-204.

Takahashi, K.I., ed., 2001, U.S. Geological Survey coalbed methane field conference, May 9-10, 2001: U.S. Geological Survey, Open-File Report 01-0235, CD-ROM.Takahashi, K.U., N. Suzuki, and H. Saito, 2014, Compositional and isotopic changes in expelled and residual gases during anhydrous closed-system pyrolysis of hydrogen-rich Eocene subbituminous coal: International Journal of Coal Geology, v. 127, p. 14-23.Takeda, K., S. Miyagawa, and S. Taguchi, 1990, Effect of coal properties on combustibility of coal injected to blast furnace: Iron and Steel Society Conference Proceedings, v. 49, p. 455-464.

Talyzina, N.M., 1998, Fluorescence intensity in Early Cambrian acritarchs from Estonia: Review of Palaeobotany and Palynology, v. 100, p. 99-108.Tamulonis, K.L., T.E. Jordan, and B. Slater, 2011, Carbon dioxide storage potential for the Queenston Formation near the AES Cayuga coal-fired power plant in Tompkins County, New York: Environmental Geosciences Journal, v. 18, no. 1.Tandon, S.K., and M.R. Gibling, 1994, Calcrete and coal in late Carboniferous cyclothems of Nova Scotia, Canada: climate and sea-level changes linked: Geology, v. 22, p. 755-758.Tang, T.Q., P. Ji, G.-L. Lai, C.-Q. Chi, Z.-S. Liu, and X.-L. Wu, 2012, Diverse microbial community from the coalbeds of the Ordos Basin, China: International Journal of Coal Geology, v. 90-91, p. 21-33. (biogenic methane)Tang, Y., 1993, Secondary macropores and mosaic structure in a telemagmatic metamorphosed coal and their significance in exploration for natural gas, Henan, China: Organic Geochemistry, v. 20, p. 283-294.Tang, Y., P.D. Jenden, A. Nigrini, and S.C. Teerman, 1996, Modeling early methane generation in coal: Energy and Fuels, v. 10, p. 659-671.Tao, F.F., and L.D. Brown, 1988, Anisotropic coke formation during coal slurry heating in the coal liquefaction process: Fuel, v. 67, p. 4-9.Tao, M., B. Shi, J. Li, W. Wang, X. Li, and B. Gao, 2007, Secondary biological coalbed gas in the Xinji area, Anhui province, China: Evidence from the geochemical features and secondary changes: International Journal of Coal Geology, v. 71, p. 358-370.Tao, S., D. Tang, H. Xu, J. Liang, and X. Shi, 2013, Organic geochemistry and elements distribution in Dahuangshan oil shale, southern Junggar Basin: Origin of organic matter and depositional environment: International Journal of Coal Geology, v. 115, p. 41-51.Tao, S., Y. Wang, D. Tang, H. Xu, Y. Lv, W. He, and Y. Li, 2012, Dynamic variation effects of coal permeability during the coalbed methane development process in the Qinshui Basin, China: International Journal of Coal Geology, v. 93, p. 16-22.Taraba, B., Z. Michalec, V. Michalcová, T. Blejchař, M. Bojko, and M. Kozubková, 2014, CFD simulations of the effect of wind on the spontaneous heating of coal stockpiles: Fuel, v. 118, p. 107-112.Taulbee, D., S.H. Poe, T. Robl, and B. Keogh, 1989, Density gradient centrifugation separation and characterization of maceral groups from a mixed maceral bituminous coal: Energy Fuels, v. 3, p. 662-670.Taulbee, D.N., J.C. Hower, and S.F. Greb, 1991, Examination of micrinite concentrates from the Cannel City coal bed of eastern Kentucky: proposed mechanism of formation: Organic Geochemistry, v. 17, p. 557-565.

Tayebi Khorami, M., S. Chehreh Chelgani, J. C. Hower, and E. Jorjani, 2011, Studies of relationships between Free Swelling Index (FSI) and coal quality by regression and Adaptive Neuro Fuzzy Inference System: International Journal of Coal Geology, v. 85, p. 65-71.Taylor, G.H., 1961, Development of optical properties of coke during carbonization: Fuel, v. 40, p. 465-471.Taylor, G.H., and A.C. Cook, 1962, Sclerotinite in coal—its petrology and classification: Geological Magazine, v. 99, p. 41-52.Taylor, G.H., and M. Teichmüller, 1993, Observations on fluorinite and fluorescent vitrinite with the transmission electron microscope: International Journal of Coal Geology, v. 22, p. 61-82.Taylor, G.H., and M. Teichmuller, 1993, Observations on fluorinite and fluorescing vitrinite with the transmission electron microscope: International Journal of Coal Geology, v. 22, p. 61-82.Taylor, G.H., and M. Teichmuller, 1993, Observations on fluorinite and fluorescing vitrinite with the transmission electron microscope: International Journal of Coal Geology, v. 22, p. 61-82.Taylor, G.H., and S.Y. Liu, 1987, Biodegradation in coals and other organic-rich rocks: Fuel, v. 66, p. 1269-1273.Taylor, G.H., and S.Y. Liu, 1987, Biodegradation in coals and other organic-rich rocks: Fuel, v. 66, p. 1269-1273.Taylor, G.H., and S.Y. Liu, 1987, Biodegradation in coals and other organic-rich rocks: Fuel, v. 66, p. 1269-1273.Taylor, G.H., and S.Y. Liu, 1987, Biodegradation in coals and other organic-rich rocks: Fuel, v. 66, p. 1269-1273.Taylor, G.H., and S.Y. Liu, 1989, Micrinite—its nature, origin and significance: International Journal of Coal Geology, v. 14, p. 29-46.

Taylor, G.H., M. Shibaoka, and S.Y. Liu, 1982, Characterization of huminite macerals: Fuel, v. 61, p. 1197-1200.Taylor, G.H., M. Teichmuller, A. Davis, C.F.K. Diessel, R. Littke, and P. Robert, 1998, Organic petrology: Berlin & Stuttgart, Gebruder Borntraeger, 704 p.

Taff, J.A., 1899, An albertite-like asphalt in the Choctaw Nation, Indian Territory: American Journal of Science, 4 th Series, v. 8, p. 219-224.Taff, J.A., 1909, Grahamite deposits of southeastern Oklahoma, in C.W. Hayes and W. Lindgren, Contributions to economic geology 1908: U.S. Geological Survey, Bulletin 380, p. 286-297.

Takemura, Y., and Y. Saito, 1994, Action of H2O in coal: effect of H2O addition upon nickel-catalyzed hydroliquefaction of brown Morwell coal: Journal of Coal Quality, v. 13, p. 7-9.

Tavoulareas, E.S., 1991, Fluidized-bed combustion technology, in J.M. Hollander, ed., Annual Review of Energy and the Environment: Palo Alto, Annual Reviews, Inc., Energy and the Environment, v. 16, p. 25-57.

Taylor, G.H., and S.Y. Liu, 1989, The maturation of liptinite, in C.G. Thomas and M.G. Strachan, eds., Proceedings of the Macerals ’89 symposium: North Ryde, NSW, CSIRO, p. 11-1 to 11-8.

Taylor, G.H., M. Teichmuller, A. Davis, C.F.K. Diessel, R. Littke, and P. Robert, 1998, Organic petrology: Berlin & Stuttgart, Gebruder Borntraeger, 704 p.Taylor, G.H., M. Teichmuller, A. Davis, C.F.K. Diessel, R. Littke, and P. Robert, 1998, Organic petrology: Berlin & Stuttgart, Gebruder Borntraeger, 704 p. (Rock-Eval p. 498)Taylor, G.H., M. Teichmüller, A. Davis, C.F.K. Diessel, R. Littke, and P. Robert, 1998, Organic petrology: Berlin Stuttgart, Gebrüder Borntraeger, 704 p.Taylor, G.H., M. Teichmüller, A. Davis, C.F.K. Diessel, R. Littke, and P. Robert, 1998, Organic Petrology: Berlin-Stuttgart, Gebrüder Borntraeger, 704 p.Taylor, G.H., M. Teichmüller, A. Davis, C.F.K. Diessel, R. Littke, and P. Robert, 1998, Organic Petrology: Berlin-Stuttgart, Gebrüder Borntraeger, 704 p.Taylor, G.H., M.-T. Mackowsky, and B. Alpern, 1967, The behavior of inertinite during carbonization: Fuel, v. 46, p. 431-440.Taylor, G.H., S.Y. Liu, and C.F.K. Diessel, 1989, The cold-climate origin of inertinite-rich Gondwana coals: International Journal of Coal Geology, v. 11, p. 1-22.Taylor, G.H., S.Y. Liu, and M. Smyth, 1988, New light on the orign of Cooper basin oil: APEA Journal, v. 28, part 1, p. 303-309.Taylor, G.H., S.Y. Liu, and M. Teichmüller, 1991, Bituminite—a TEM view: International Journal of Coal Geology, v. 18, p. 71-85.Taylor, T.N., E.L. Taylor, and M. Krings, 2009, Paleobotany: the biology and evolution of fossil plants, second edition: New York, Elsevier, 1230 p. (p. 29, coal balls are not known after the Carboniferous-Permian)Tedesco, S. A., 2004, Coalbed methane in the Illinois Basin: an update: Tuscaloosa, Alabama, University of Alabama, College of Continuing Studies, 2004 International Coalbed Methane Symposium Proceedings, paper 0420, 7 p.Tedesco, S. A., 2004, Stratigraphic framework and architecture of the deltas of Pennsylvanian age in the Forest City and Cherokee Basins and their impact on coalbed methane production: Tuscaloosa, Alabama, University of Alabama, College of Continuing Studies, 2004 International Coalbed Methane Symposium Proceedings, paper 0421, 9 p.

Tedesco, S.A., 2003, Exploration strategies for coal bed methane in the Western Region of the Interior Coal Province (abstract): AAPG Mid-Continent Section Meeting, Official Program Book, p.44.Tedesco, S.A., 2003, Positive factors dominate negatives for Illinois Basin coalbed methane: Oil & Gas Journal, v. 101.13, p. 28-32.

Teerman, S.C., B.J. Cardott, R.W., Harding, M.J. Lemos De Sousa, D.R. Logan, H.J. Pinheiro, M. Reinhardt, C.L. Thompson-Rizer, and R.A. Woods, 1994, Source rock/dispersed organic matter characterization - TSOP Research Subcommittee results: Organic Geochemistry, v. 22, p. 11-25.Teerman, S.C., J.C. Crelling, and G.B. Glass, 1987, Fluorescence spectral analysis of resinite macerals from coals of the Hanna Formation, Wyoming, U.S.A.: International Journal of Coal Geology, v. 7, p. 315-334.Tegelaar, E.W., J. Wattendorff, and J.W. de Leeuw, 1993, Possible effects of chemical heterogeneity in higher land plant cuticles on the preservation of its ultrastructure upon fossilization: Review of Palaeobotany and Palynology, v. 77, p. 149-170.Tegelaar, E.W., J.W. De Leeuw, S. Derenne, and C. Largeau, 1989, A reappraisal of kerogen formation: Geochimica et Cosmochimica Acta, v. 53, p. 3103-3106.Teichmüller, M., 1974, Generation of petroleum-like substances in coal seams as seen under the microscope: Advances in Organic Geochemistry 1973: Paris, Editions Technip, p. 321-349.Teichmuller, M., 1978, Nachweis von Graptolithen -- periderm in geschieferten gesteinen mit hilfe kohlenpetrologischer methoden: Neues Jahrbuch fur Geologie und Palaeontologie, Monatschefte, 1978, no. 7, p. 430-447.Teichmüller, M., 1982, Fluorescence microscopical changes of liptinites and vitrinites during coalification and their relationship to bitumen generation and coking behaviour: TSOP Special Publication No. 1, 74 p.

Teichmuller, M., 1986, Organic petrology of source rocks, history and state of the art: Organic Geochemistry, v. 10, p. 581-599.

Teichmüller, M., 1989, The genesis of coal from the viewpoint of coal petrology: International Journal of Coal Geology, v. 12, p. 1-87.Teichmüller, M., 1990, The genesis of coal from the viewpoint of coal geology: International Journal of Coal Geology, v. 16, p. 121-124.Teichmüller, M., 1992, Organic petrology in the service to archaeology: International Journal of Coal Geology, v. 20, p. 1-21.Teichmuller, M., and B. Durand, 1983, Fluorescence microscopical rank studies on liptinites and vitrinites in peat and coals, and comparison with results of the Rock-Eval pyrolysis: International Journal of Coal Geology, v. 2, p. 197-230.Teichmüller, M., and B. Durand, 1983, Fluorescence microscopical rank studies on liptinites and vitrinites in peat and coals, and comparison with results of the Rock-Eval pyrolysis: International Journal of Coal Geology, v. 2, p. 197-230.Teichmuller, M., and B. Durand, 1983, Fluorescence microscopical rank studies on liptinites and vitrinites in peat and coals, and comparison with results of the Rock-Eval pyrolysis: International Journal of Coal Geology, v. 2, p. 197-230. (Tmax influenced by petrographic composition, p. 222)Teichmuller, M., and K. Ottenjann, 1977, Liptinite und lipoide stoffe in einem erdolmuttergestein: Erdol und Kohle - Erdgas - Petrochemie, v. 30, no. 9, p. 387-398.Teichmuller, M., and M. Wolf, 1977, Application of fluorescence microscopy in coal petrology and oil exploration: Journal of Microscopy, v. 109, part 1, p. 49-73.Teichmüller, M., and M. Wolf, 1977, Application of fluorescence microscopy in coal petrology and oil exploration: Journal of Microscopy, v. 109, part 1, p. 49-73.Teichmuller, M., and R. Teichmuller, 1981, The significance of coalification studies to geology -- a review: Bulletin Des Centres De Recherchese Exploration-Production Elf Aquitaine, v. 5, p. 491-534.Teichmuller, M., and R. Teichmuller, 1981, The significance of coalification studies to geology: Bulletin des Centres de Recherches Exploration -- Production, Elf-Aquitaine, v. 5, p. 491-534.

Tedesco, S.A., 2003, Coalbed methane in the Illinois Basin, in M.R. Silverman, ed., Emerging coalbed methane plays of North America (part 2): Denver, CO, Petroleum Frontiers, v. 18, no. 4, p. 26-37.Tedesco, S.A., 2003, Coalbed methane in the Western Interior Basin, in M.R. Silverman, ed., Emerging coalbed methane plays of North America (part 2): Denver, CO, Petroleum Frontiers, v. 18, no. 4, p. 11-25.

Teerman, S.C., and R.J. Hwang, 1991, Evaluation of the liquid hydrocarbon potential of coal by artificial maturation techniques, in P.K. Mukhopadhyay, M.G. Fowler, and W.G. Dow, eds., Selected papers from the symposium on coal and terrestrial organic matter as a source rock for petroleum: Organic Geochemistry, v. 17, p. 749-764.

Teichmuller, M., 1982, The importance of coal petrology in prospecting for oil and natural gas, in E. Stach and others, Stach's textbook of coal petrology, third edition: Berlin, Gebruder Borntraeger, p. 399-412.Teichmuller, M., 1986, Organic petrology of source rocks, history and state of the art, in D. Leythaeuser and J. Rullkotter, eds., Advances in organic geochemistry 1985, part I: Petroleum geochemistry: Organic Geochemistry, v. 10, p. 581-599.

Teichmüller, M., 1987, Organic material and very low-grade metamorphism, in M. Frey, ed., Low temperature metamorphism: New York, Chapman and Hall, p. 114-161.Teichmüller, M., 1987, Recent advances in coalfication studies and their application to geology, in A.C. Scott, ed., Coal and coal-bearing strata: recent advances: Boston, Blackwell Scientific Publications, Geological Society Special Publication 32, p. 127-169.Teichmüller, M., 1987, Recent advances in coalification studies and their application to geology, in A.C. Scott, ed., Coal and coal-bearing strata: recent advances: Boston, Blackwell Scientific Publications, Geological Society Special Publication 32, p. 127-169.

Teichmuller, M., and R. Teichmuller, 1982, Das inkohlungsbild des lippstadter gewolbes: Fortschritte in der Geologie von Rheinland und Westfalen, v. 30, p. 223-239.Telle, W. R., and D. A. Thompson, 1987, Preliminary characterization of the coalbed methane potential of the Cahaba coal field, central Alabama: Tuscaloosa, Alabama, University of Alabama, 1987 Coalbed Methane Symposium Proceedings, p. 141-151.Telle, W. R., and D. A. Thompson, 1988, The Cahaba coal field: a potential coalbed methane development area in central Alabama: Tuscaloosa, Alabama, University of Alabama, School of Mines and Energy Development Research Report 88-1, 174 p.Telle, W.R., D.A. Thompson, L.K. Lottman, and P.G. Malone, 1987, Preliminary burial - thermal history investigations of the Black Warrior basin: implications for coalbed methane and conventional hydrocarbon development: Tuscaloosa, Alabama, Proceedings of the 1987 Coalbed Methane Symposium, paper 8713, p. 37-50.Tercan, A.E., and B. Sohrabian, 2013, Multivariate geostatistical simulation of coal quality data by independent components: International Journal of Coal Geology, v. 112, p. 53-66.Tercan, A.E., B. Űnver, M.A. Hindistan, G. Ertunç, F. Atalay, S. Űnal, and Y. Killioğlu, 2013, Seam modeling and resource estimation in the coalfields of western Anatolia: International Journal of Coal Geology, v. 112, p. 94-106.Terrell, H., 2010, Oil shale—a peak at future technology: World Oil, v. 231, no. 9, p. 19.Teteryuk, V.K., 1988, Miospores of peat-forming plants in coal seams as indicators of the conditions of peat accumulation: International Geology Review, v. 30, p. 842-852.Tewalt, S.J., J.C. Willett, and R.B. Finkelman, 2005, The world coal quality inventory: a status report: International Journal of Coal Geology, v. 63, p. 190-194.Thakur, P., K. Aminian, and S. Schatzel, eds., 2014, Coal bed methane from prospect to pipeline: New York, Elsevier, 440 p.

Thielemann, T., B. Cramer, and A. Schippers, 2004, Coalbed methane in the Ruhr Basin, Germany: a renewable energy resource?: Organic Geochemistry, v. 35, p. 1537-1549.Thielemann, T., B.M. Krooss, R. Littke, and D.H. Welte, 2001, Does coal mining induce methane emissions through the lithosphere/atmosphere boundary in the Ruhr basin, Germany?: Journal of Geochemical Exploration, v. 74, p. 219-231.Thielemann, T., B.M. Krooss, R. Littke, and D.H. Welte, 2001, Does coal mining induce methane emissions through the lithosphere/atmosphere boundary in the Ruhr basin, Germany?: Journal of Geochemical Exploration, v. 74, p. 219-231.Thiessen, R., 1920, Compilation and composition of bituminous coals: Journal of Geology, v. 28, p. 185-209.Thiessen, R., 1920, Compilation and composition of bituminous coals: Journal of Geology, v. 28, p. 185-209.Thiessen, R., 1920, Structure in Paleozoic bituminous coals: U.S. Bureau of Mines Bulletin 117, 296 p.Thiessen, R., 1920, Structure in Paleozoic bituminous coals: U.S. Bureau of Mines Bulletin 117, 296 p.Thiessen, R., 1925, Origin of the boghead coals: U.S. Geological Survey Professional Paper 132-I, p. 121-135.Thiessen, R., 1925, Origin of the boghead coals: U.S. Geological Survey Professional Paper 132-I, p. 121-138.Thiessen, R., 1926, The micro-structure of coal: Journal of the Royal Society of Arts, London, v. 74, p. 535-557.Thiessen, R., 1926, The micro-structure of coal: London, Journal of the Royal Society of Arts, v. 74, p. 535-557.

Thiessen, R., 1930, Splint coal: American Institute of Mining and Metallurgical Engineers Transactions, v. 88, p. 644-671.

Thiessen, R., 1931, Recently developed methods of research in the constitution of coal and their application to Illinois coals: Illinois State Geological Survey Bulletin 60, p. 117-147.Thiessen, R., 1937, Classification of coal from the viewpoint of a paleobotanist: Transactions of the American Institute of Mining and Metallurgical Engineers, v. 88, p. 419-437.Thiessen, R., 1947, What is coal?: U.S. Bureau of Mines Technical Circular 7397, 53 p.Thiessen, R., and G.C. Sprunk, 1935, Microscopic and petrographic studies of certain American coals: U.S. Bureau of Mines Technical Paper 564, 71 p.Thiessen, R., and G.C. Sprunk, 1936, The origin of the finely divided or granular opague matter in splint coals: Fuel, v. 15, p. 304-315.Thiessen, R., and G.C. Sprunk, 1936, The origin of the finely divided or granular opaque matter in splint coals: Fuel, v. 15, p. 304-315.Thiessen, R., and W. Francis, 1929, Terminology in coal research: U.S. Bureau of Mines Technical Paper 446, 27 p.Thiessen, R., and W. Francis, 1929, Terminology in coal research: U.S. Bureau of Mines Technical Paper 446, 27 p.Thimons, B., and F.N. Kissell, 1973, Diffusion of methane through coal: Fuel, v. 52, p. 274-280.Thimons, B., and F.N. Kissell, 1973, Diffusion of methane through coal: Fuel, v. 52, p. 274-280.Thomas, B.M., 1982, Land-plant source rocks for oil and their significance in Australian basins: APEA Journal, v. 22, part 1, p. 164-178.Thomas, C.G., M. Shibaoka, E. Gawronski, M.E. Gosnell, and D. Phong-anant, 1992, Reactive inertinite in pf combustion. Part I: a laser microreactor — its use in coal research: Fuel,Thomas, C.G., M. Shibaoka, E. Gawronski, M.E. Gosnell, and D. Phong-anant, 1992, Reactive inertinite in pf combustion. Part II: determination of reactive inertinite in pf combustion: Fuel,

Thielemann, T., and R. Littke, 1999, Examples of the methane exchange between litho- and atmosphere: the coal bearing Ruhr basin, Germany, in M. Mastalerz, M. Glikson, and S.D. Golding, eds., Coalbed methane: scientific, environmental and economic evaluation: Boston, Kluwer Academic Publishers, p. 555-558.Thielemann, T., and R. Littke, 1999, Examples of the methane exchange between litho- and atmosphere: the coal bearing Ruhr basin, Germany, in M. Mastalerz, M. Glikson, and S.D. Golding, eds., Coalbed methane: scientific, environmental and economic evaluation: Boston, Kluwer Academic Publishers, p. 555-558.

Thiessen, R., 1929, Some recent developments on the constitution of coal, in Proceedings of the second international conference on bituminous coal, v. 1: Pittsburgh, Carnegie Institute of Technology, p. 695-767.

Thiessen, R., 1931, Recently developed methods of research in the constitution of coal and their application to Illinois coals, in Papers presented at the Quarter Centennial Celebration of the ISGS: Illinois State Geological Survey Bulletin 60, p. 117-147.

Thomas, C.G., M. Shibaoka, E. Gawronski, M.E. Gosnell, and L.F. Brunckhorst, 1989, Macerals’ fusion behaviour in thermal coals, in C.G. Thomas and M.G. Strachan, eds., Proceedings of the Macerals ’89 symposium: North Ryde, NSW, CSIRO, p. 4-1 to 4-35.Thomas, C.G., M.E. Gosnell, E. Gawronski, and P.M. Nicholls, 1995, Measurement of coal reactivity in the ironmaking blastfurnace raceway, in J.A. Pajares and J.M.D. Tascon, eds., Coal science: New York, Elsevier, Coal Science and Technology 24, v. 1, p. 535-538.

Thomas, C.G., M.E. Gosnell, E. Gawronski, D. Phong-Anant, and M. Shibaoka, 1993, The behaviour of inertinite macerals under pulverised fuel (pf) combustion conditions: Organic Geochemistry, v. 20, p. 779-788.Thomas, C.G., M.E. Gosnell, E. Gawronski, D. Phong-Anant, and M. Shibaoka, 1993, The behaviour of inertinite macerals under pulverized fuel (pf) combustion conditions: Organic Geochemistry, v. 20, p. 779-788.Thomas, J., and H.H. Damberger, 1976, Internal surface area, moisture content and porosity of Illinois coals: variations with coal rank: Illinois State Geological Survey, Circular 493, 38 p.Thomas, J., Jr., and H.H. Damberger, 1976, Internal surface area, moisture content, and porosity of Illinois coals: variations with coal rank: Illinois State Geological Survey Circular 493, 38 p.Thomas, J., Jr., and H.H. Damberger, 1976, Internal surface area, moisture content, and porosity of Illinois coals: variations with coal rank: Illinois State Geological Survey Circular 493, 38 p.

Thomas, L., 1992, Handbook of practical coal geology: Chichester, John Wiley & Sons, 338 p.Thomas, L., 1992, Handbook of practical coal geology: New York, John Wiley & Sons, 338 p.Thomas, L., 1992, Handbook of practical coal geology: New York, John Wiley & Sons, 338 p.

Thomas, L., 2002, Coal geology: Hoboken, N.J., John Wiley & Sons, Inc., 384 p. (coal gasification and liquefaction, p. 271-279)Thomas, L., 2002, Coal geology: Hoboken, New Jersey, John Wiley & Sons, Inc., 384 p.Thomas, L., 2002, Coal geology: San Francisco, CA, John Wiley & Sons, Ltd, 384 p.Thomas, L., 2013, Coal geology (second edition): Hoboken, New Jersey, Wiley-Blackwell, 444 p.Thomas, L., 2013, Coal geology (second edition): Hoboken, New Jersey, Wiley-Blackwell, 444 p.Thomas, L., 2013, Coal geology (second edition): Hoboken, New Jersey, Wiley-Blackwell, 444 p. (Coal as an alternative energy source, p. 303-337)Thomas, L., 2013, Coal geology (second edition): Hoboken, New Jersey, Wiley-Blackwell, 444 p. (Coal as an alternative energy source, p. 303-337)Thomas, L., 2013, Coal geology (second edition): Hoboken, New Jersey, Wiley-Blackwell, 444 p. (Coal exploration and data collection, p. 151-184)Thomas, L., 2013, Coal geology (second edition): Hoboken, New Jersey, Wiley-Blackwell, 444 p. (Coal sampling and analysis, p. 137-149)

Thomas, M., 2013, Unlocking Indonesia’s CBM potential: Hart Energy Publishing, E&P, v. 86, no. 2, p. 98-103.Thompson, C.L., and H. Dembicki, Jr., 1986, Optical characteristics of amorphous kerogens and the hydrocarbon-generating potential of source rocks: International Journal of Coal Geology, v. 6, p. 229-249.Thompson, C.L., P.C. Lyons, R.B. Finkelman, F.W. Brown, and P.G. Hatcher, 1983, Microscopy of sclerotinites in the coal beds of the central part of the Appalachian coal field, U.S.A.: Journal of Microscopy, v. 132, pt. 3, p. 267-277.Thompson, R.R., 2000, History of applied coal petrology in the United States, III. Contributions to applied coal and coke petrology at the Bethlehem Steel Corporation: International Journal of Coal Geology, v. 42, p. 115-128.Thompson, R.R., 2000, History of applied coal petrology in the United States. III. Contributions to applied coal and coke petrology at the Bethlehem Steel Corporation: International Journal of Coal Geology, v. 42, p. 115-128.Thompson, R.R., and L.G. Benedict, 1974, Vitrinite reflectance as an indicator of coal metamorphism for cokemaking: GSA Special Paper 153, p. 95-108.Thompson, R.R., and L.G. Benedict, 1974, Vitrinite reflectance as an indicator of coal metamorphism for cokemaking: GSA Special Paper 153, p. 95-108.Thompson, R.R., and L.G. Benedict, 1976, Coal composition and its influence on cokemaking: Iron and Steel Maker, v. 3, no. 2, p. 21-31.

Thompson, S., R.J. Morley, P.C. Barnard, and B.S. Cooper, 1985, Facies recognition of some Tertiary coals applied to prediction of oil source rock occurrence: Marine and Petroleum Geology, v. 2, p. 288-297.Thompson-Rizer, C.L., 1987, Some optical characteristics of solid bitumen in visual kerogen preparations: Organic Geochemistry, v. 11, p. 385-392.Thompson-Rizer, C.L., 1987, Some optical characteristics of solid bitumen in visual kerogen preparations: Organic Geochemistry, v. 11, p. 385-392.Thompson-Rizer, C.L., 1993, Optical description of amorphous kerogen in both thin sections and isolated kerogen preparations of Precambrian to Eocene shale samples: Precambrian Research, v. 61, p. 181-190.Thompson-Rizer, C.L., 1993, Optical description of amorphous kerogen in both thin sections and isolated kerogen preparations of Precambrian to Eocene shale samples: Precambrian Research, v. 61, p. 181-190. (doubly polished thin section)Thompson-Rizer, C.L., and R.A. Woods, 1987, Microspectrofluorescence measurements of coals and petroleum source rocks: International Journal of Coal Geology, v. 7, p. 85-104.Thompson-Rizer, C.L., R.A. Woods, and K. Ottenjann, 1988, Quantitative fluorescence results from sample exchange studies: Organic Geochemistry, v. 12, p. 323-332.Thorpe, A.N., F.E. Senftle, R.B. Finkelman, F.T. Dulong, and N.H. Bostick, 1998, Change in the magnetic properties of bituminous coal intruded by an igneous dike, Dutch Creek Mine, Pitkin County, Colorado: International Journal of Coal Geology, v. 36, p. 243-258.Tiffney, B.H., ed., 1989, Phytodebris: notes for a short course: Botanical Society of America, Paleobotanical Section, 124 p.

Thomas, J., Jr., and H.H. Damberger, 1976, Porosity and internal surface area of Illinois agglomerating coals, in C.J. Smith, compiler, Proceedings of the coal agglomeration and conversion symposium: West Virginia Geological and Economic Survey, p. 25-36.Thomas, J., Jr., and H.H. Damberger, 1976, Porosity and internal surface area of Illinois agglomerating coals, in C.J. Smith, compiler, Proceedings of the coal agglomeration and conversion symposium: West Virginia Geological and Economic Survey, p. 25-36.

Thomas, L., 1997, Economics of coal geology, in M. Podemski, S. Dybova-Jachowicz, K. Jaworowski, J. Jureczka, and R. Wagner, eds., Proceedings of the XIII International Congress on the Carboniferous and Permian: Warszawa, Polish Geological Institute, v. 157, pt. 2, p. 395-403.

Thomas, M., 2010, Responsible development of oil shale: Proceedings of the 29 th Oil Shale Symposium, Colorado School of Mines, Golden, CO (CD-ROM)

Thompson, R.R., and L.G. Benedict, 1976, Relationship between cokeability and petrographic composition of agglomerating coals, in C.J. Smith, compiler, Proceedings of the coal agglomeration and conversion symposium: West Virginia Geological and Economic Survey, p. 63-83.Thompson, S., B.S. Cooper, and P.C. Barnard, 1994, Some examples and possible explanations for oil generation from coals and coaly sequences, in A.C. Scott and A.J. Fleet, eds., Coal and coal-bearing strata as oil-prone source rocks?: London, The Geological Society Special Publication 77, p. 119-137.Thompson, S., B.S. Cooper, R.J. Morley, and P.C. Barnard, 1985, Oil-generating coals, in B.M. Thomas and others, eds., Petroleum geochemistry in exploration of the Norwegian shelf: London, Graham and Trotman, p. 59-73.

Timofeev, P.P., and L.I. Bogolyubova, 1981, Organic matter in Cretaceous "black shales" from the Atlantic and Pacific Oceans and their relation to the problems of oil and gas formation: Bulletin Centres Recherches Exploration-Production, Elf Aquitaine, v. 5, p. 575-600.Ting, F.T.C., 1975, Quantitative fluorescence microscopy and fluorescence characteristics of thermally altered liptinites: American Association of Stratigraphic Palynologists, Palynology, v. 1, p. 27-32.Ting, F.T.C., 1977, Microscopical investigation of the transformation (diagenesis) from peat to lignite: Journal of Microscopy, v. 109, pt. 1, p. 75-83.Ting, F.T.C., 1977, Origin and spacing of cleats in coal beds: Journal of Pressure Vessel Technology, v. 99, p. 624-626.

Ting, F.T.C., 1984, Paragenetic relationship of thermal maturation (coalification) and tectonic framework of some Canadian Rocky Mountain coals: Organic Geochemistry, v. 5, p. 278-281.Ting, F.T.C., 1987, Optical anisotropism and its relationship with some physical and chemical properties of coal: Organic Geochemistry, v. 11, p. 403-405.Ting, F.T.C., 1987, Optical anisotropism and its relationship with some physical and chemical properties of coal: Organic Geochemistry, v. 11, p. 403-405.Ting, F.T.C., 1991, Review of vitrinite reflectance techniques and applications: Organic Geochemistry, v. 17, p. 269-270.Ting, F.T.C., and H.-B. Lo, 1975, Fluorescence characteristics of thermo-altered exinites (sporinites): Fuel, v. 54, p. 201-204.Ting, F.T.C., and H.-B. Lo, 1978, New techniques for measuring maximum reflectance of vitrinite and dispersed vitrinite in sediments: Fuel, v. 57, p. 717-721.Ting, F.T.C., and J.A. Sitler, 1989, Comparative studies of the reflectivity of vitrinite and sporinite: Organic Geochemistry, v. 14, p. 247-252.Ting, F.T.C., and P.B. Wang, 1984, Coal anisotropism and its relationship to methane concentration in coal (abstract): AAPG Bulletin, v. 68, p. 535.

Tissot, B., B. Durand, J. Espitalie, and A. Combaz, 1974, Influence of nature and diagenesis of organic matter in formation of petroleum: AAPG Bulletin, v. 58, p. 499-506.Tissot, B.P., 1979, Effects on prolific petroleum source rocks and major coal deposits caused by sea-level changes: Nature, v. 277, p. 463-465.Tissot, B.P., 1984, Recent advances in petroleum geochemistry applied to hydrocarbon exploration: AAPG Bulletin, v. 68, p. 545-563.Tissot, B.P., and D.H. Welte, 1984, Petroleum formation and occurrence, second revised and enlarged edition: New York, Springer-Verlag, 699 p.Tissot, B.P., and D.H. Welte, 1984, Petroleum formation and occurrence, second revised and enlarged edition: New York, Springer-Verlag, 699 p. (see p. 241-245,495-507).Tissot, B.P., and D.H. Welte, 1984, Petroleum formation and occurrence, second revised and enlarged edition: New York, Springer-Verlag, p. 229-253.Tissot, B.P., R. Pelet, and Ph. Ungerer, 1987, Thermal history of sedimentary basins, maturation indices, and kinetics of oil and gas generation: AAPG Bulletin, v. 71, p. 1445-1466.Tiwary, S.N., Mukhdeo, and P.S.M. Tripathi, 1994, High volatile bituminous Indian coal: effect of gamma-irradiation on the electrical resistivity: Erdo und Kohle-Erdgas-Petrochemie, v. 47, p. 424-426.Tobin, R.C., and B.L. Claxton, 2000, Multidisciplinary thermal maturity studies using vitrinite reflectance and fluid inclusion microthermometry: a new calibration of old techniques: AAPG Bulletin, v. 84, p. 1647-1665.Todhunter, C., I. Crane, J. Foreman, M. Franklin, J. Hill, J. Perry, and G. Meszaros, 2012, Oilfield horizontal drilling technology used to degas an Australian coal mine: World Oil, v. 233, no. 2, p. 103-110.Tomeczek, J., and H. Palugniok, 2002, Kinetics of mineral matter transformation during coal combustion: Fuel, v. 81, p. 1251-1258.

Toole-O’Neil, B., S.J. Tewalt, R.B. Finkelman, and D.J. Akers, 1999, Mercury concentration in coal—unraveling the puzzle: Fuel, v. 78, p. 47-54.Toraño, J., S. Torno, M. Menendez, M. Gent, and J. Velasco, 2009, Models of methane behavior in auxiliary ventilation of underground coal mining: International Journal of Coal Geology, v. 80, p. 35-43.Torkelson, D., 2009, Wyoming CBM permits slow to a trickle: American Oil & Gas Reporter, v. 52, no. 8, p. 121-123.Torre, M.D., R.F. Mählmann, and W.G. Ernst, 1997, Experimental study on the pressure dependence of vitrinite maturation: Geochimica et Cosmochimica Acta, v. 61, p. 2921-2928.Torrent, J.G., I.S. Armada, and R.A. Pedreira, 1988, A correlation between composition and explosibility index for coal dust: Fuel, v. 67, p. 1629-1632.

Tilton, J.G., 1076, Gas from coal deposits, in Natural gas from unconventional geologic sources: Washington, D.C., National Academy of Sciences, p. 206-229.

Ting, F.T.C., 1978, Petrographic techniques in coal analysis, in C. Karr, Jr., ed., Analytical methods for coal and coal products, v. 1: New York, Academic Press, p. 3-26.Ting, F.T.C., 1978, Petrographic techniques in coal analysis, in C. Karr, Jr., ed., Analytical methods for coal and coal products, v. 1: New York, Academic Press, p. 3-26.Ting, F.T.C., 1981, Uniaxial and biaxial vitrinite reflectance models and their relationship to palaeotectonics, in J. Brooks, ed., Organic maturation studies and fossil fuel exploration: New York, Academic Press, p. 379-392.Ting, F.T.C., 1982, Coal macerals, in R.A. Meyers, ed., Coal structure: New York, Academic Press, p. 7-49.Ting, F.T.C., 1982, Coal macerals, in R.A. Meyers, ed., Coal structure: New York, Academic Press, p. 7-49.

Ting, F.T.C., and W. Spackman, 1975, The coal lithotype concept and seam profiles: Compte Rendu, 17 th International Congress on Stratigraphy and Geology of the Carboniferous.Tissot, B., and D.H. Welte, 1984, Petroleum formation and occurrence, 2nd ed.: New York, Springer-Verlag, 699 p.

Tomlinson, G., D. Gray, and M. Neuworth, 1985, The impact of rank-related coal properties on the response of coals to continuous direct liquefaction processes, in Proceedings, 1985 International Conference on Coal Science: Pergamon Press, p. 3-6.Tomschey, O., 1991, Distribution of trace elements in coal and their host phases in a Lower Eocene coal seam of Hungary, in P. Bertrand, ed., Coal: formation, occurrence and related properties: Bulletin de la Societe Geologique de France, v. 162, p. 267-270.

Torres-Ordonez, R.J., W.H. Calkins, and M.T. Klein, 1990, Distribution of organic-sulfur-containing structures in high organic sulfur coals, in W.L. Orr and C.M. White, eds., Geochemistry of sulfur in fossil fuels: Washington, D.C., American Chemical Society Symposium Series 429, p. 287-295.Toth, D.J., I. Lerche, D.E. Petroy, R.J. Meyer, and C.G.St.C. Kendall, 1983, Vitrinite reflectance and the derivation of heat flow changes with time, in M. Bjoroy et al., eds., Advances in organic geochemistry 1981: New York, John Wiley & Sons Ltd., p. 588-596.Toxopeus, J.M.A. Buiskool, 1983, Selection criteria for the use of vitrinite reflectance as a maturity tool, in J. Brooks, ed., Petroleum geochemistry and exploration of Europe: Boston, Blackwell Scientific Publications, p. 295-307.

Traverse, A., ed., 1994, Sedimentation of organic particles: Cambridge University Press, 544 p.Tremain, C.M., 1990, Coalbed methane development in Colorado, September 1990: Colorado Geological Survey Information Series 32, 35 p.Tremain, C.M., and others, 1983, The coal bed methane resources of Colorado: Colorado Geological Survey Map Series 19, 1 plate.

Treworgy, C.G., C. Chenoweth, and M.H. Bargh, 1995, Availability of coal resources for mining in Illinois: Galatia Quadrangle, Saline County, southern Illinois: Illinois State Geological Survey, Illinois Minerals 113, 38 p.Treworgy, C.G., C.A. Chenoweth, and M. Justice, 1996, Availability of coal resources for mining in Illinois: Atwater, Collinsville, and Nokomis Quadrangles, Christian, Macoupin, Madison, Montgomery, and St. Clair Counties: Illinois State Geological Survey, Open File Series OFS 1996-2, 33 p.Treworgy, C.G., C.A. Chenoweth, and R.J. Jacobsen, 1996, Availability of coal resources for mining in Illinois: Newton and Princeville Quadrangles, Jasper, Peoria, and Stark Counties: Illinois State Geological Survey, Open File Series OFS 1996-3, 38 p.Treworgy, C.G., G.K. Coats, and M. Bargh, 1994, Availability of coal resources for mining in Illinois: Middleton Quadrangle, central Illinois: Illinois State Geological Survey, Circular 554, 48 p.Treworgy, C.G., L.E. Bengal, and A.G. Dingwell, 1978, Reserves and resources of surface-minable coal in Illinois: Illinois State Geological Survey, Circular 504, 44 p.Tricker, P.M., 1992, Chitinozoan reflectance in the Lower Paleozoic of the Welsh basin: Terra Nova, v. 4, p. 231-237.Tricker, P.M., J.E.A. Marshall, and T.D. Badman, 1992, Chitinozoan reflectance: a lower Palaeozoic thermal maturity indicator: Marine and Petroleum Geology, v. 9, p. 302-307.Trimble, A.S., and H.C. Hower, 2003, Studies of the relationship between coal petrology and grinding properties: International Journal of Coal Geology, v. 54, p. 253-260.Trimble, A.S., and H.C. Hower, 2003, Studies of the relationship between coal petrology and grinding properties: International Journal of Coal Geology, v. 54, p. 253-260.Trimble, A.S., and J.C. Hower, 2000, Maceral/microlithotype analysis of the progressive grinding of a central Appalachian high-volatile bituminous coal blend: Minerals and Metallurgical Processing, v. 17, p. 234-243.Trimble, A.S., and J.C. Hower, 2000, Maceral/microlithotype analysis of the progressive grinding of a central Appalachian high-volatile bituminous coal blend: Minerals and Metallurgical Processing, v. 17, p. 234-243.

Triolo, M., D.O. Ogbe, and A.S. Lawal, 2000, Considerations for water disposal and management in the development of coalbed methane resources in rural Alaska: Journal of Canadian Petroleum Technology, v. 39, p. 41-47.Tripp, B.T., 2004, Gilsonite, an unusual Utah resource: Utah Geological Survey, Survey Notes, v. 36, no. 3, p. 1-3, 7.

Trumbull, J.V.A., 1960, Coal fields of the United States (sheet 1): U.S. Geological Survey map, scale 1:5,000,000.Tsai, C.-Y., and A.W. Scaroni, 1987, Pyrolysis and combustion of bituminous coal fractions in an entrained-flow reactor: Energy and Fuels, v. 1, p. 263-269.

Tsai, L.L., and L.-C. Sun, 2002, Suppression of vitrinite reflectance implications from a case study (abstract): TSOP Annual Meeting, abstract A3.2.6.Tsai, S.C., 1982, Fundamentals of coal beneficiation and utilization: New York, Elsevier Scientific Publ. Co., Coal Science and Technology, v. 2, 375 p.Tsotsis, T.T., H. Patel, B.F. Najafi, D. Racherla, M.A. Knackstedt, and M. Sahimi, 2004, Overview of laboratory and modeling studies of carbon dioxide sequestration in coal beds: Industrial and Engineering Chemistry Research, v. 43, p. 2887-2901.

Turner, B.R., and D. Richardson, 2004, Geological controls on the sulphur content of coal seams in the Northumberland coalfield, northeast England: International Journal of Coal Geology, v. 60, p. 169-196.Turner, B.R., and D. Richardson, 2004, Geological controls on the sulphur content of coal seams in the Northumberland coalfield, northeast England: International Journal of Coal Geology, v. 60, p. 169-196.

Tyler, R., A.R. Scott, W.R. Kaiser, and R.G. McMurry, 1997, The application of a coalbed methane producibility model in defining coalbed methane exploration fairways and sweet spots: examples from the San Juan, Sand Wash, and Piceance basins: Austin, Texas, Bureau of Economic Geology, Report of Investigations 244, 59 p.Tyler, R., and A.R. Scott, 1997, Defining coalbed gas exploration fairways in low permeability, hydrocarbon overpressured basins: an example from the Piceance basin, northwest Colorado: International Coalbed Methane Symposium, Paper 9717, 13 p.Tyler, R., N. Zhou, R.G. McMurray, M.L.W. Jackson, and C.M. Tremain, 1992, Selected references related to coalbed methane in the Greater Green River, Piceance, Powder River, Raton, and San Juan basins: Colorado Geological Survey Information Series 35, 77 p.Tyler, R., W.R. Kaiser, A.R. Scott, and D.S. Hamilton, 1997, The potential for coalbed gas exploration and production in the Greater Green River Basin, southwest Wyoming and northwest Colorado: The Mountain Geologist, v. 34, no. 1, p. 7-24.Tyler, R., W.R. Kaiser, A.R. Scott, D.S. Hamilton, and W.A. Ambrose, 1995, Geologic and hydrologic assessment of natural gas from coal: Greater Green River, Piceance, Powder River, and Raton basins, western United States: Bureau of Economic Geology, Report of Investigations 228, 219 p.Tyler, S.A., E.S. Barghoorn, and L.P. Barrett, 1957, Anthracitic coal from Precambrian upper Huronian black shale of the Iron River District, northern Michigan: GSA Bulletin, v. 68, p. 1293-1304. (algal coal)

Trask, C.B., 1987, Cyclothems in the Carbondale Formation (Pennsylvanian: Desmoinesian Series) of La Salle County, Illinois, in D.L. Biggs, ed., North-Central Section of the Geological Society of America: Geological Society of America Centennial Field Guide, v. 3, p. 221-226.Traverse, A., 1955, Occurrence of the oil-forming alga Botryococcus in lignites and other Tertiary sediments: Micropaleontology, v. 1, p. 343-349.Traverse, A., 1994, Sedimentation of palynomorphs and palynodebris: an introduction, in A. Traverse, ed., Sedimentation of organic particles: Cambridge University Press, p. 1-8.

Tremain, C.M., S.E. Laubach, and N.H. Whitehead, III, 1991, Coal fracture (cleat) patterns in Upper Cretaceous Fruitland Formation, San Juan basin, Colorado and New Mexico - implications for coalbed methane exploration and development, in S.D. Schwochow, D.K. Murray, and M.F. Fahy, eds., Coalbed methane of western North America: Denver, Rocky Mountain Association of Geologists, p. 49-59.Tremain, C.M., S.E. Laubach, and N.H. Whitehead, III, 1994, Fracture (cleat) patterns in Upper Cretaceous Fruitland Formation coal seams, San Juan basin, in W.B. Ayers, Jr. and W.R. Kaiser, eds., Coalbed methane in the Upper Cretaceous Fruitland Formation, San Juan basin, New Mexico and Colorado: New Mexico Bureau of Mines and Mineral Resources, Bulletin 146, p. 87-102.

Trinkle, E.J., and J.C. Hower, 1984, Petrography of the Middle Pennsylvanian Upper Elkhorn no. 3 coal of eastern Kentucky, U.S.A., in R.A. Rahmani and R.M. Flores, eds., Sedimentology of coal and coal-bearing sequences: Boston, Blackwell Scientific Publications, International Association of Sedimentologists Special Publication 7, p. 349-360.

Trost, P.B., 2003, Coalbed methane potential of the Bellingham Basin, Washington, in M.R. Silverman, ed., Emerging coalbed methane plays of North America (part 3): Petroleum Frontiers, v. 19, no. 2, p. 1-8.

Tsai, L.L., 1995, Petrographic fabric analyses of sporinite: a new technique in coal characterization, in J.A. Pajares and J.M.D. Tascon, eds., Coal science: New York, Elsevier, Coal Science and Technology 24, v. 1, p. 247-250.

Tully, J., compiler, 1996, Coal fields of the conterminous United States: U.S. Geological Survey Open-File Report 96-92, one sheet, scale 1:5,000,000. http://pubs.usgs.gov/of/1996/of96-092/index.htm

Turner, J.A., K.M. Thomas, D.S. Way, and D.G. Richards, 1995, The reactivity of coal chars in the blast furnace, in J.A. Pajares and J.M.D. Tascon, eds., Coal science: New York, Elsevier, Coal Science and Technology 24, v. 1, p. 547-550.Tyler, R., A.R. Scott, and W.R. Kaiser, 1999, Defining coalbed methane exploration fairways: an example from the Piceance basin, Rocky Mountain foreland, western United States, in M. Mastalerz, M. Glikson, and S.D. Golding, eds., Coalbed methane: scientific, environmental and economic evaluation: Boston, Kluwer Academic Publishers, p. 67-87.

Tyson, R.V., 1987, The genesis and palynofacies characteristics of marine petroleum source rocks, in J. Brooks and A.J. Fleet, eds., Marine petroleum source rocks: Geological Society Special Publication 26, p. 47-67.

Tyson, R.V., 1994, Sedimentary organic matter: organic facies and palynofacies: New York, Chapman and Hall, 615 p.Tyson, R.V., 1995, Sedimentary organic matter; organic facies and palynofacies: New York, Chapman & Hall, 615 p.Tyson, R.V., 2001, Sedimentation rate, dilution, preservation and total organic carbon: some results of a modelling study: Organic Geochemistry, v. 32, p. 333-339.Tyson, R.V., 2006, Calibration of hydrogen indices with microscopy: a review, reanalysis and new results using the fluorescence scale: Organic Geochemistry, v. 37, p. 45-63.

U.S. Environmental Protection Agency, 1998, Legal issues related to coalbed methane storage in abandoned coal mines in Virginia, West Virginia, Pennsylvania, Utah, Colorado and Alabama: U.S. Environmental Protection Agency, Coalbed Methane Outreach Program, Document No. 60933, 62 p.

U.S. Office of Coal Research, 1967, Methods of analyzing and testing coal and coke: U.S. Bureau of Mines Bulletin 638, 85 p.U.S.G.S., 2004, Total Petroleum System and assessment of coalbed gas in the Powder River Basin Province, Wyoming and Montana: U.S. Geological Survey Digital Data Series DDS-69-C, CD-ROM.Uhl, D., A.A. Hamad, H. Kerp, and K. Bandel, 2007, Evidence for palaeo-wildfire in the Late Permian palaeotropics—charcoalified wood from the Um Irna Formation of Jordan: Review of Palaeobotany and Palynology, v. 144, p. 221-230.Ujiie, Y., N. Sherwood, M. Faiz, and R.W.T. Wilkins, 2004, Thermal maturity and suppressed vitrinite reflectance for Neogene petroleum source rocks of Japan: AAPG Bulletin, v. 88, p. 1335-1356.Ujiié, Y., N. Sherwood, M. Faiz, and R.W.T. Wilkins, 2004, Thermal maturity and suppressed vitrinite reflectance for Neogene petroleum source rocks of Japan: AAPG Bulletin, v. 88, p. 1335-1356.Ulery, J.P., 1988, Geologic factors influencing the gas content of coalbeds in southwestern Pennsylvania: U.S. Bureau of Mines, Report of Investigations 9195, 26 p.Ulrich, G., and S. Bower, 2008, Active methanogenesis and acetate utilization in Powder River Basin coals, United States: International Journal of Coal Geology, v. 76, p. 25-33.

Umekwe, P., J. Mongrain, M. Ahmadi, and C. Hanks, 2013, Assessment of Alaska’s North Slope oil field capacity to sequester CO2: Natural Resources Research, v. 22, p. 45-58.Unsworth, J.F., C.S. Fowler, and L.F. Jones, 1989, Moisture in coal: 2. Maceral effects on pore structure: Fuel, v. 68, p. 18-26.Unsworth, J.F., D.J. Barratt, and P.T. Roberts, 1991, Coal quality and combustion performance: an international perspective: New York, Elsevier Scientific Publ. Co., Coal Science and Technology, v. 19, 638 p.Ural, S., 2007, Quantification of crystalline (mineral) matter in some Turkish coals using interactive Rietveld-based X-ray diffractometry: International Journal of Coal Geology, v. 71, p. 176-184.Ural, S., and M. Akyildiz, 2004, Studies of the relationship between mineral matter and grinding properties of low-rank coals: International Journal of Coal Geology, v. 60, p. 81-84.Urban, N.R., K. Ernst, and S. Bernasconi, 1999, Addition of sulfur to organic matter during early diagenesis of lake sediments: Geochimica et Cosmochimica Acta, v. 63, p. 837-853.Uribe, C.A., and F.H. Perez, 1985, Proposal for coal classification: Fuel, v. 64, p. 147-150.USBM, 1967, Methods of analyzing and testing coal and coke: U.S. Bureau of Mines Bulletin 638, 85 p.USDOE, 1977, Oil shales and tar sands, a bibliography: U.S. Department of Energy, Technical Information Center, TID-3367.USGS, 1976, Coal resource classification system of the U.S. Bureau of Mines and U.S. Geological Survey: USGS Bulletin 1450-B, 7 p.

Utting, J., and H. Wielens, 1992, Organic petrology, thermal maturity, geology, and petroleum source rock potential of lower Permian coal, Karoo supersystem, Zambia: Energy Sources, v. 14, p. 337-354.Vainikka, P., and M. Hupa, 2012, Review on bromine in solid fuels. Part 1: Natural occurrence: Fuel, v. 95, p. 1-14.Valceva, S.P., 1979, Reflectance of macerals from bright brown coal, Pernik basin: Fuel, v. 58, p. 55-58.Valentim, B., and J.C. Hower, 2010, Influence of feed and sampling systems on element partitioning in Kentucky fly ash: International Journal of Coal Geology, v. 82, p. 94-104.Valentim, B., J.C. Hower, J.M.K. O’Keefe, S. Rodrigues, J. Ribeiro, and A. Guedes, 2013, Notes on the origin of altered macerals in the Ragged Edge of the Pennsylvanian (Asturian) Herring coalbed, western Kentucky: International Journal of Coal Geology, v. 115, p. 24-40.Valentim, B., M.J. Lemos de Sousa, P. Abelha, D. Boavida, and I. Gulyurtlu, 2006, Combustion studies in a fluidized bed—the link between temperature, NOx and N2O formation, char morphology and coal type: International Journal of Coal Geology, v. 67, p. 191-201.

Tyson, R.V., 1989, Late Jurassic palynofacies trends, Piper and Kimmeridge Clay Formations, UK onshore and northern North Sea, in D.J. Batten and M.C. Keen, eds., Northwest European micropalaeontology and palynology: New York, Halsted Press, p. 135-172.Tyson, R.V., 1990, Automated transmitted light kerogen typing by image analysis: 1. General aspects and program description, in W.J.J. Fermont and J.W. Weegink, eds., International symposium on organic petrology: Mededelingen Rijks Geologische Dienst, v. 45, p. 139-149.Tyson, R.V., 1993, Palynofacies analysis, in D.G. Jenkins, ed., Applied micropalaeontology: Boston, Kluwer Academic Publishers, p. 153-191.

U.S. Department of Energy (DOE), 2010, 2010 carbon sequestration atlas of the United States and Canada: U.S. Department of Energy, NETL, Atlas III, http://www.netl.doe.gov/technologies/carbon_seq/refshelf/atlasIII/index.html

U.S. Geological Survey Oil Shale Assessment Team, 2008, Fischer assays of oil-shale drill cores and rotary cuttings from the greater Green River Basin, southwestern Wyoming: U.S. Geological Survey Open-File Report 2008-1152, 2 chapters, 1 CD-ROM. http://pubs.usgs.gov/of/2008/1152/U.S. Geological Survey Oil Shale Assessment Team, 2010, Oil shale and nahcolite resources of the Piceance Basin, Colorado: U.S. Geological Survey Digital Data Series DDS-69-Y, 7 chapters, pages variable. http://pubs.usgs.gov/dds/dds-069/dds-069-y/U.S. Geological Survey Oil Shale Assessment Team, 2010, Oil shale resources of the Uinta Basin, Utah and Colorado: U.S. Geological Survey Digital Data Series DDS-69-BB, 7 chapters, pages variable. http://pubs.usgs.gov/dds/dds-069/dds-069-bb/U.S. Geological Survey Oil Shale Assessment Team, 2011, Assessment of in-place oil shale resources of the Green River Formation, Greater Green River Basin in Wyoming, Colorado, and Utah: U.S. Geological Survey, Fact Sheet 2011-3063, 4 p. http://pubs.usgs.gov/fs/2011/3063/pdf/FS11-3063.pdfU.S. Geological Survey Oil Shale Assessment Team, 2011, Oil shale resources of the Eocene Green River Formation, Greater Green River Basin, Wyoming, Colorado, and Utah: U.S. Geological Survey, Digital Data Series DDS-69-DD, 6 chapters. http://pubs.usgs.gov/dds/dds-069/dds-069-dd/REPORTS/69_DD_CHAPTERS.pdf

Uludağ, S., 2007, The spontaneous combustion index and its application: past, present, and future, in G.B. Stracher, ed., Geology of coal fires: case studies from around the world: GSA Reviews in Engineering Geology 18, p. 15-22.

USGS, 2009. http://energy.cr.usgs.gov/other/oil_shale/USGS, 2013, The gigaton question: How much geologic carbon storage potential does the United States have?: http://www.usgs.gov/blogs/features/usgs_top_story/the-gigaton-question-how-much-geologic-carbon-storage-potential-does-the-united-states-have/?from=image USGS, Photomicrograph atlas. http://energy.usgs.gov/Coal/OrganicPetrology/PhotomicrographAtlas.aspx

Valentim, B., M.J. Lemos de Sousa, P. Abelha, D. Boavida, and I. Gulyurtlu, 2006, The identification of unusual microscopic features in coal and their derived chars: influence on coal fluidized bed combustion: International Journal of Coal Geology, v. 67, p. 202-211.Valentim, B., S. Rodrigues, S. Ribeiro, G. Pereira, A. Guedes, and I. Suárez-Ruiz, 2013, Relationships between the optical properties of coal macerals and the chars resulting from fluidized bed pyrolysis: International Journal of Coal Geology, v. 111, p. 80-89.Valentim, B., S. Rodrigues, S. Ribeiro, G. Pereira, A. Guedes, and I. Suárez-Ruiz, 2013, Relationships between the optical properties of coal macerals and the chars resulting from fluidized bed pyrolysis: International Journal of Coal Geology, v. 111, p. 80-89.Valentine, B.J., E.A. Morrissey, A.J. Park, M.E. Reidy, and P.C. Hackley, 2013, Development of web-based organic petrology photomicrograph atlases and internet resources for professionals and students: International Journal of Coal Geology, v. 111, p. 106-111.Valentine, B.J., E.A. Morrissey, A.J. Park, M.E. Reidy, and P.C. Hackley, 2013, Development of web-based organic petrology photomicrograph atlases and internet resources for professionals and students: International Journal of Coal Geology, v. 111, p. 106-111.Valia, H.S., 1989, Prediction of coke strength after reaction with CO2 from coal analyses at Inland Steel Company: Iron and Steelmaker, v. 16, p. 77-87.Valia, H.S., 1990, Effects of coal oxidation on cokemaking: Proceedings Ironmaking Conference, v. 49, p. 199-209.

Valia, H.S., and M. Mastalerz, 2004, Indiana coals and the steel industry: Indiana Geological Survey, Special Report 64, 28 p.Valia, H.S., and W. Hooper, 1994, Use of reverts and non-coking coals in metallurgical cokemaking: Iron and Steel Society Conference Proceedings, v. 53, p. 89-105.Valia, H.S., D.D. Kaegi, V.I. Addes, and D.A. Zuke, 1989, Production and use of high CSR coke at Inland Steel Company: Iron and Steel Society Conference Proceedings, v. 48, p. 133-146.Valk, M., ed., 1995, Atmospheric fluidized bed coal combustion: research, development and application: New York, Elsevier Scientific Publ. Co., Coal Science and Technology, v. 22, 462 p.Valkovic, V., 1983, Trace elements in coal: Boca Raton, Florida, CRC Press.Valkovic, V., ed., 1983, Trace elements in coal: Boca Raton, Florida, CRC Press, v. 1, p. 35-104.Van Berge, P.F., M. Goni, M.E. Collinson, P.J. Barrie, J.S. Sinninghe Damste, and J.W. de Leeuw, 1994, Chemical and microscopic characterization of outer seed coats of fossil and extant water plants: Geochimica et Cosmochimica Acta, v. 58, p. 3823-3844.Van Bergen, F., C. Spiers, G. Floor, and P. Bots, 2009, Strain development in unconfined coals exposed to CO2, CH4 and Ar: Effect of moisture: International Journal of Coal Geology, v. 77, p. 43-53.Van Bergen, F., H.J.M. Pagnier, H.C.E. Schreurs, A.P.C. Paaij, C.N. Hamelinck, K.-H.A.A. Wolf, O.H. Barzandji, D. Jansen, and G.J. Ruijg, 2001, Inventory of the potential for enhanced coalbed methane production with carbon dioxide disposal in the Netherlands: Tuscaloosa, Alabama, Proceedings, International Coalbed Methane Symposium, Paper 117, p. 271-282.Van Bergen, F., J. Gale, K.J. Damen, and A.F.B. Wildenborg, 2004, Worldwide selection of early opportunities for CO2-enhanced oil recovery and CO2-enhanced coal bed methane production: Energy, v. 29, p. 1611-1621.Van Bergen, F., S. Hol, and C. Spiers, 2011, Stress-strain response of pre-compacted granular coal samples exposed to CO2, CH4, He and Ar: International Journal of Coal Geology, v. 86, p. 241-253.Van Bergen, P.F., A.C. Scott, P.J. Barrie, J.W. de Leeuw, and M.E. Collinson, 1994, The chemical composition of upper Carboniferous pteridosperm cuticles: Organic Geochemistry, v. 21, p. 107-112.

Van de Wetering, N., and J. Esterle, 2014, Short note: On petrographically differentiating the anatomical characteristics of saprotrophied and carbonised inertinite group macerals: International Journal of Coal Geology, v. 131, p. 106-108.Van de Wetering, N., J. Graciano Mendonça Filho, and J. Esterle, 2013, Palynofacies changes and their reflection on preservation of peat accumulation stages in the Late Permian coal measures of the Bowen Basin, Australia: A new system for coal palynofacies characterization: International Journal of Coal Geology, v. 120, p. 57-70.

Van der Flier-Keller, E., and P. Bartier, 1993, Application of geographic information systems to interpretation of coal geochemistry data: International Journal of Coal Geology, v. 24, p. 293-308.

Van Der Meer, B., and P. Egberts, 2008, Calculating subsurface CO2 storage capacities: The Leading Edge, v. 27, p. 502.Van Dijk, P., J. Zhang, W. Jun, C. Luenzer, and K.-H. Wolf, 2011, Assessment of the contribution of in-situ combustion of coal to greenhouse gas emission; based on a comparison of Chinese mining information to previous remote sensing estimates: International Journal of Coal Geology, v. 86, p. 108-119.Van Dijk, P., J. Zhang, W. Jun, C. Luenzer, and K.-H. Wolf, 2011, Assessment of the contribution of in-situ combustion of coal to greenhouse gas emission; based on a comparison of Chinese mining information to previous remote sensing estimates: International Journal of Coal Geology, v. 86, p. 108-119.Van Dyk, J.C., M.J. Keyser, and M. Coertzen, 2006, Syngas production from South African coal sources using Sasol-Lurgi gasifiers: International Journal of Coal Geology, v. 65, p. 243-253.Van Gijzel, P., 1967, Autofluorescence of fossil pollen and spores with special reference to age determination and coalification: Leidse Geol. Meded., v. 40, p. 263-317.Van Gijzel, P., 1967, Palynology and fluorescence microscopy: Review of Palaeobotany and Palynology, v. 2, p. 49-79.

Van Gijzel, P., 1978, Recent developments in the application of quantitative fluorescence microscopy in palynology and paleobotany: Annales des Mines de Belgique, v. 7-8, p. 836-851.Van Gijzel, P., 1979, Manual of the techniques and some geological applications of fluorescence microscopy: American Association of Stratigraphic Palynologists, 12 Annual Meeting Workshop, Dallas, 55 p.

Valia, H.S., 1993, Coal quality reserve evaluation for the iron and steel industry, in S.-H. Chiang, ed., Coal—energy and the environment: Tenth Annual International Pittsburgh Coal Conference, Proceedings, p. 305-310.

Van Bergen, P.F., M.E. Collinson, A.C. Scott, and J.W. De Leeuw, 1995, Unusual resin chemistry from upper Carboniferous pteridosperm resin rodlets, in K. Anderson and J.C. Crelling, eds., Amber, resinite, and fossil resin: Washington, D.C., American Chemical Society, Symposium Series 617, p. 149-169.Van Bergen, P.F., N.M.M. Janssen, M. Alferink, and J.H.F. Kerp, 1990, Recognition of organic matter types in standard palynological slides, in W.J.J. Fermont and J.W. Weegink, eds., International symposium on organic petrology: Mededelingen Rijks Geologische Dienst, v. 45, p. 9-21.

Van der Flier-Keller, E., and F. Goodarzi, 1991, Geological controls on major and trace element characteristics of Cretaceous coals of Vancouver Island, Canada, in P. Bertrand, ed., Coal: formation, occurrence and related properties: Bulletin de la Societe Geologique de France, v. 162, p. 255-265.

Van der Heijden, E., F. Bouman, and J.J. Boon, 1994, Anatomy of recent and peatified Calluna vulgaris stems: implications for coal maceral formation: International Journal of Coal Geology, v. 25, p. 1-25.

Van Gijzel, P., 1971, Review of the UV-fluorescence microphotometry of fresh and fossil exines and exosporia, in J. Brooks, P.R. Grant, M. Muir, P. Van Gijzel, and G. Shaw, eds., Sporopollenin: New York, Academic Press, p. 659-685.Van Gijzel, P., 1975, Polychromatic UV-fluorescence microphotometry of fresh and fossil plant substances, with special reference to the location and identification of dispersed organic material in rocks, in B. Alpern, ed., Colloque International Petrographie de la Matiere Organique des Sediments: Paris, CNRS, p. 67-91.

Van Gijzel, P., 1981, Application of the geomicrophotometry of kerogen, solid hydrocarbons and crude oils to petroleum exploration, in J. Brooks, ed., Organic maturation studies and fossil fuel exploration: London, Academic Press, p. 351-377.Van Gijzel, P., 1981, Applications of the geomicrophotometry of kerogen, solid hydrocarbons and crude oils to petroleum exploration, in J. Brooks, ed., Organic maturation studies and fossil fuel exploration: New York, Academic Press, p. 351-377.Van Gijzel, P., 1981, Applications of the geomicrophotometry of kerogen, solid hydrocarbons and crude oils to petroleum exploration, in J. Brooks, ed., Organic maturation studies and fossil fuel exploration: San Francisco, Academic Press, p. 351-377.Van Gijzel, P., 1982, Characterization and identification of kerogen and bitumen and determination of thermal maturation by means of qualitative and quantitative microscopical techniques, in F.L. Staplin and others, eds., How to assess maturation and paleotemperatures: SEPM Short Course 7, p. 159-216.

Van Gijzel, P., C.R. Robison, M.A. Smith, K.K. Bissada, I. Lerche, and J. Liu, 1992, Thermal history modeling of the Georges Bank, U.S.A.: thermal inversion of Transmittance Color Index (TCI) and vitrinite reflectance data: Applied Geochemistry, v. 7, p. 135-143.Van Hemert, P., K.-H.A.A. Wolf, and E.S.J. Rudolph, 2012, Output gas stream composition from methane saturated coal during injection of nitrogen, carbon dioxide, a nitrogen-carbon dioxide mixture and a hydrogen-carbon dioxide mixture: International Journal of Coal Geology, v. 89, p. 108-113.Van Hinte, J.E., 1978, Geohistory analysis - application of micropaleontology in exploration geology: AAPG Bulletin, v. 62, p. 201-222.Van Koeverden, J.H., D.A. Karlsen, L. Schwark, A. Chpitsglouz, and K. Backer-Owe, 2010, Oil-prone Lower Carboniferous coals in the Norwegian Barents Sea: Implications for a Palaeozoic petroleum system: Journal of Petroleum Geology, v. 33, p. 155-181.

Van Krevelen, D.W., 1981, Coal. Typology, chemistry, physics and constitution: New York, Elsevier Scientific Publishing Company, Coal Science and Technology v. 3, 514 p.Van Krevelen, D.W., 1981, Coal: typology, chemistry, physics, and constitution: New York, Elsevier Scientific Publishing Company, Coal Science and Technology v. 3, 514 p.Van Krevelen, D.W., 1981, Coal: typology, chemistry, physics, and constitution: New York, Elsevier Scientific Publishing Company, Coal Science and Technology v. 3, 514 p.Van Krevelen, D.W., 1982, Development of coal research: Fuel, v. 61, p. 786-790.Van Krevelen, D.W., 1984, Organic geochemistry—old and new: Organic Geochemistry, v. 6, p. 1-10.Van Krevelen, D.W., 1993, Coal. Typology,-physics-chemistry-constitution (third completely revised edition): New York, Elsevier Scientific Publishing Company, 979 p.Van Niekerk, D., and J.P. Mathews, 2009, Molecular representations of Permian-aged vitrinite-rich and inertinite-rich South African coals: Fuel, v. 89, p. 73-82.Van Niekerk, D., G.D. Mitchell, and J.P. Mathews, 2010, Petrographic and reflectance analysis of solvent-swelled and solvent-extracted South African vitrinite-rich and inertinite-rich coals: International Journal of Coal Geology, v. 81, p. 45-52.Van Niekerk, D., G.D. Mitchell, and J.P. Mathews, 2010, Petrographic and reflectance analysis of solvent-swelled and solvent-extracted South African vitrinite-rich and inertinite-rich coals: International Journal of Coal Geology, v. 81, p. 45-52.Van Niekerk, D., P.M. Hallack, and J.P. Mathews, 2009, Solvent swelling behavior of Permian-aged South African vitrinite-rich and inertinite-rich coals: Fuel, v. 89, p. 19-25.Van Niekerk, D., R.J. Pugmire, M.S. Solum, P.C. Painter, and J.P. Mathews, 2008, Structural characterization of vitrinite-rich and inertinite-rich Permian-aged South African bituminous coals: International Journal of Coal Geology, v. 76, p. 290-300.Van Rensburg, W.C.J., 1979, Coal gasification and liquefaction: Austin, TX, Bureau of Economic Geology, Mineral Resource Circular 62, 42 p.Van Vergen, F., P. Krzystolik, N. van Wageningen, H. Pagnier, B. Jura, J. Skiba, P. Winthaegen, and Z. Kobiela, 2009, Production of gas from coal seams in the Upper Silesian coal basin in Poland in the post-injection period of an ECBM pilot site: International Journal of Coal Geology, v. 77, p. 175-187.Van Voast, W.A., 2003, Geochemical signature of formation waters associated with coalbed methane: AAPG Bulletin, v. 87, p. 667-676.Van Voast, W.A., 2003, Geochemical signature of formation waters associated with coalbed methane: AAPG Bulletin, v. 87, p. 667-676.

Vanden Berg, M.D., 2008, Basin-wide evaluation of the uppermost Green River Formation’s oil-shale resource, Uinta Basin, Utah and Colorado: Utah Geological Survey, Special Study 128, 19 p. http://www.geology.utah.gov/online/ss/ss-128/ss-128txt.pdf; http://geology.utah.gov/emp/oilshale/pdf/oilshale1108.pdf Vanden Berg, M.D., 2009, Evaluating Utah’s oil shale resource: Utah Geological Survey, Survey Notes, v. 41, no. 1, p. 7-8, 12.Vanden Berg, M.D., J.R. Dyni, and D.E. Tabet, 2006, Utah oil shale information database: Utah Geological Survey Open-File Report 469, CD-ROM.

Vandenbroucke, M., 2003, Kerogen: from types to models of chemical structure: Oil & Gas Science Technology, Revue de l’Institut Français du Pétrole, v. 58, no. 2, p. 243-269.Vandenbroucke, M., and C. Largeau, 2007, Kerogen origin, evolution and structure: Organic Geochemistry, v. 38, p. 719-833.Vaninetti, G.E., and C.F. Busch, 1982, Mineral analysis of ash data: a utility perspective: Journal of Coal Quality, v. 1, p. 22-31.

Varma, A.K., 1996, Facies control on the petrographic composition of inertitic coals: International Journal of Coal Geology, v. 30, p. 327-335.Varma, A.K., 1996, Influence of petrographical composition on coking behavior of inertinite-rich coals: International Journal of Coal Geology, v. 30, p. 337-347.Varma, A.K., 2002, Thermogravimetric investigations in prediction of coking behavior and coke properties derived from inertinite rich coals: Fuel, v. 81, p. 1321-1334.Varma, A.K., M. Kumar, V.K. Saxena, A. Sarkar, and S.K. Banerjee, 2014, Petrographic controls on combustion behavior of inertinite rich coal and char and fly ash formation: Fuel, v. 128, p. 199-209.Varma, S., J. Underschultz, T. Dance, R. Langford, J. Esterle, K. Dodds, and D. van Gent, 2009, Regional study on potential CO2 geosequestration in the Collie Basin and the southern Perth Basin of western Australia: Marine and Petroleum Geology, v. 26, p. 1255-1273.Varol, Ö.N., I.H. Demirel, R.B. Rickards, and Y. Günay, 2006, Source rock characteristics and biostratigraphy of the Lower Silurian (Telychian) organic-rich shales at Akyaka, central Taurus region, Turkey: Marine and Petroleum Geology, v. 23, p. 901-911.Vasilakos, N.P., ed., 1988, Advances in coal chemistry: Athens, Greece, Theophrastus Publications S.A., 360 p.Vassilev, S.V., and C.G. Vassileva, 1996, Occurrence, abundance and origin of minerals in coals and coal ashes: Fuel Processing Technology, v. 48, p. 85-106.

Van Gijzel, P., 1982, Characterization and identification of kerogen and bitumen and determination of thermal maturation by means of qualitative and quantitative microscopical techniques, in F.L. Staplin and others, eds., How to assess maturation and paleotemperatures: SEPM, Short Course 7, p. 159-216.Van Gijzel, P., 1982, Characterization and identification of kerogen and bitumen and determination of thermal maturation by means of qualitative and quantitative microscopical techniques, in F.L. Staplin and others, How to assess maturation and paleotemperatures: SEPM Short Course Notes 7, p. 159-216.Van Gijzel, P., 1990, Transmittance colour index (TCI) of amorphous organic matter: a new thermal maturity indicator for hydrocarbon source rocks, and its correlation with mean vitrinite reflectance and thermal alteration index (TAI), in W.J.J. Fermont and J.W. Weegink, eds., International symposium on organic petrology: Mededelingen Rijks Geologische Dienst, v. 45, p. 49-64.

Van Krevelen, D.W., 1963, Geochemistry of coal, in I.A. Breger, ed., Organic geochemistry: The Macmillan Company, A Pergamon Press Book, Earth Science Series, Monograph 16, p. 183-247.Van Krevelen, D.W., 1981, Chemistry of coal weathering and spontaneous combustion, in Coal: typology - chemistry - physics - constitution: New York, Elsevier Scientific Publishing Company, p. 238-262.

Vanden Berg, M.D., 2007, Utah’s oil shale deposits: Stratigraphy and resource evaluation: Presentation at 27th Oil Shale Symposium, 28 p. http://geology.utah.gov/emp/oilshale/pdf/oilshale1007.pdf

Vanden Bert, M.D., and D.E. Tabet, 2007, Re-examination of Utah’s oil shale deposits: Historical database and new resource evaluation: Presentation at GSA Rocky Mountain Section meeting, 42 p. http://geology.utah.gov/emp/oilshale/pdf/oilshale0507.pdf

Varma, A.K., 1995, Microtextural and reflectance studies of cokes derived from inertinite rich coals, in J.A. Pajares and J.M.D. Tascon, eds., Coal science: New York, Elsevier, Coal Science and Technology 24, v. 1, p. 1065-1068.

Vassilev, S.V., and C.G. Vassileva, 2008, A new approach for the combined chemical and mineral classification of the inorganic matter in coal. 1. Chemical and mineral classification systems: Fuel, v. 88, p. 235-245.Vassilev, S.V., and C.G. Vassileva, 2008, A new approach for the combined chemical and mineral classification of the inorganic matter in coal. 1. Chemical and mineral classification systems: Fuel, v. 88, p. 235-245.Vassilev, S.V., and J.M.D. Tascon, 2003, Methods for characterization of inorganic and mineral matter in coal: a critical overview: Energy Fuels, v. 17, p. 271-281.Vassilev, S.V., C.G. Vassileva, A.I. Karayigit, Y. Bulut, A. Alastuey, and X. Querol, 2005, Phase-mineral and chemical composition of composite samples from feed coals, bottom ashes and fly ashes at the Soma power station, Turkey: International Journal of Coal Geology, v. 61, p. 35-63.Vassilev, S.V., C.G. Vassileva, A.I. Karayigit, Y. Bulut, A. Alastuey, and X. Querol, 2005, Phase-mineral and chemical composition of fractions separated from composite fly ashes at the Soma power station, Turkey: International Journal of Coal Geology, v. 61, p. 65-85.Vassilev, S.V., C.G. Vassileva, D. Baxter, and L.K. Andersen, 2008, A new approach for the combined chemical and mineral classification of the inorganic matter in coal. 2. Potential applications of the classification systems: Fuel, v. 88, p. 246-254.Vassilev, S.V., C.G. Vassileva, D. Baxter, and L.K. Andersen, 2008, A new approach for the combined chemical and mineral classification of the inorganic matter in coal. 2. Potential applications of the classification systems: Fuel, v. 88, p. 246-254.Vassilev, S.V., G.M. Eskenazy, and C.G. Vassileva, 2000, Contents, modes of occurrence and origin of chlorine and bromine in coal: Fuel, v. 79, p. 903-921.Vassilev, S.V., K. Kitano, and C.G. Vassileva, 1997, Relations between ash yield and chemical and mineral composition of coals: Fuel, v. 76, p. 3-8.Vassilev, S.V., M.G. Yossifova, and C.G. Vassileva, 1994, Mineralogy and geochemistry of Bobov Dol coals, Bulgaria: International Journal of Coal Geology, v. 26, p. 185-213.Vawter, G., 2009, Vast deposits of oil shale hold major future promise for domestic industry: American Oil & Gas Reporter, v. 52, no. 1, p. 129-133Vawter, G., 2010, Projects moving forward in oil shale: American Oil & Gas Reporter, v. 53, no. 6, p. 88-91.Veil, J.A., M.G. Puder, D. Elcock, and R.J. Redweik, Jr., 2004, A white paper describing produced water from production of crude oil, natural gas, and coal bed methane: U.S. Department of Energy, National Energy Technology Laboratory, Contract W-31-109-Eng-38, 79 p.Vejahati, F., Z. Xu, and R. Gupta, 2010, Trace elements in coal: Associations with coal and minerals and their behavior during coal utilization—A review: Fuel, v. 89, p. 904-911.Vejahati, F., Z. Xu, and R. Gupta, 2010, Trace elements in coal: Associations with coal and minerals and their behavior during coal utilization—A review: Fuel, v. 89, p. 904-911.Veld, H., and W. Fermont, 1993, Deviating vitrinite reflectance values in a Carboniferous coal sequence from the Netherlands (abstract): ICCP News, no. 8, p. 10.

Veld, H., N.N.M. Hanssen, W.J.J. Fermont, and H.J.M. Pagnier, 1993, Coal facies interpretations and vitrinite reflectance variations in Carboniferous coals from well Limbricht-1/1a, the Netherlands: 12th International Congress of Stratigraphy and Geology of the Carboniferous and Permian, Comptes Rendus, v. 1, p. 267-278.

Veld, H., R.W.T. Wilkins, X. Xianming, and C.P. Buckingham, 1997, A "fluorescence alteration of multiple macerals" (FAMM) study of Netherlands coals with "normal" and "deviating" vitrinite reflectance: Organic Geochemistry, v. 26, p. 247-255.Veld, H., R.W.T. Wilkins, X. Xianming, and C.P. Buckingham, 1997, A fluorescence alteration of multiple macerals (FAMM) study of Netherlands coals with "normal" and "deviating" vitrinite reflectance: Organic Geochemistry, v. 26, p. 247-255.Veld, H., W.J.J. Fermont, and L.F. Jegers, 1993, Organic petrological characterization of Westphalian coals from the Netherlands: correlation between Tmax, vitrinite reflectance, and hydrogen index: Organic Geochemistry, v. 20, p. 659-675.Veld, H., W.J.J. Fermont, P. David, H.J.M. Pagnier, and H. Visscher, 1996, Environmental influence on maturity parameters in Carboniferous coals of the Netherlands: International Journal of Coal Geology, v. 30, p. 37-64.

Venkatachala, B.S., 1984, Finely divided organic matter, its origin and significance as a hydrocarbon source material: Bull. Oil and Natural Gas Commission, v. 21, p. 23-45.Ventura, B., G.A. Pini, and G.G. Zuffa, 2001, Thermal history and exhumation of the northern Apennines (Italy): evidence from combined apatite fission track and vitrinite reflectance data from foreland basin sediments: Basin Research, v. 13, p. 435-448.

Verbeek, E.R., and M.A. Grout, 1993, Geometry and structural evolution of gilsonite dikes in the eastern Uinta basin, Utah: U.S. Geological Survey, Bulletin 1787-HH, 42 p.Verhelst, F., P. David, W. Fermont, L. Jegers, and A. Vervoort, 1996, Correlation of 3D-computerized tomographic scans and 2D-colour image analysis of Westphalian coal by means of multivariate statistics: International Journal of Coal Geology, v. 29, p. 1-21.Vernon, J.L., and T. Jones, 1993, Sulphur and coal: London, IEA Coal Research IEACR/57, 62 p.Veselská, V., J. Majzlan, E. Hiller, K. Petkova, L. Jurkovič, O. Ďurža, and B. Voleková-Lalinská, 2013, Geochemical characterization of arsenic-rich coal-combustion ashes buried under agricultural soils and the release of arsenic: Applied Geochemistry, v. 33, p. 153-164.Veselská, V., J. Majzlan, E. Hiller, K. Petkova, L. Jurkovič, O. Ďurža, and B. Voleková-Lalinská, 2013, Geochemical characterization of arsenic-rich coal-combustion ashes buried under agricultural soils and the release of arsenic: Applied Geochemistry, v. 33, p. 153-164.Vesper, D.J., M. Roy, and C.J. Rhoads, 2008, Selenium distribution and mode of occurrence in the Kanawha Formation, southern West Virginia, U.S.A.: International Journal of Coal Geology, v. 73, p. 237-249.

Vidal, G., 1988, A palynological preparation method: Palynology, v. 12, p. 215-220.Viete, D.R., and P.G. Ranjith, 2006, The effect of CO2 on the geomechanical and permeability behaviour of brown coal: implications for coal seam CO2 sequestration: International Journal of Coal Geology, v. 66, p. 204-216.Viete, D.R., and P.G. Ranjith, 2007, The mechanical behaviour of coal with respect to CO2 sequestration in deep coal seams: Fuel, v. 86, p. 2667-2671.Vine, J.D., 1962, Geology of uranium in coaly carbonaceous rocks: U.S. Geological Survey Professional Paper 356-D, 170 p.Vishal, V., P.G. Ranjith, and T.N. Singh, 2013, CO2 permeability of Indian bituminous coals: Implications for carbon sequestration: International Journal of Coal Geology, v. 105, p. 36-47.

Veld, H., and W.J.J. Fermont, 1990, The effect of a marine transgression on vitrinite reflectance values, in W.J.J. Fermont and J.W. Weegink, eds., International symposium on organic petrology: Mededelingen Rijks Geologische Dienst, v. 45, p. 151-169.Veld, H., and W.J.J. Fermont, 1990, The effect of a marine transgression on vitrinite reflectance values, in W.J.J. Fermont and J.W. Weegink, eds., International symposium on organic petrology: Mededelingen Rijks Geologische Dienst, v. 45, p. 151-169.

Veld, H., N.N.M. Janssen, W.J.J. Fermont, and H.J.M. Pagnier, 1993, Coal facies interpretations and vitrinite reflectance variations in Carboniferous coals from well Limbricht-1/1a, the Netherlands: 12 th International Congress of Stratigraphy and Geology of the Carboniferous and Permian, Comptes Rendus, v. 1, p. 267-278.

Venkatachala, B.S., 1981, Differentiation of amorphous organic matter types in sediments, in J. Brooks, eds., Organic maturation studies and fossil fuel exploration: San Francisco, Academic Press, p. 177-200.

Verbeek, E.R., and M.A. Grout, 1992, Structural evolution of gilsonite dikes, eastern Uinta basin, Utah, in T.D. Fouch, V.F. Nuccio, and T.C. Chidsey, Jr., eds., Hydrocarbon and mineral resources of the Uinta basin, Utah and Colorado: Salt Lake City, Utah Geological Association Guidebook 20, p. 237-255.

Vessey, S.J., and R.M. Bustin, 1999, Coalbed methane characteristics of the Mist Mountain Formation, southern Canadian Cordillera: effect of shearing and oxidation, in M. Mastalerz, M. Glikson, and S.D. Golding, eds., Coalbed methane: scientific, environmental and economic evaluation: Boston, Kluwer Academic Publishers, p. 367-384.

Vleeskens, J.M., 1983, Combustion efficiency and petrographic properties, in Proceedings, 1983 International conference on coal science: Pittsburgh Energy Technology Center, p. 599-602.

Vleeskens, J.M., and B.N. Nandi, 1986, Burnout of coals. Comparative bench-scale experiments on pulverized fuel and fluidized bed combustion: Fuel, v. 65, p. 797-802.Vleeskens, J.M., T.W.M.B. van Haasteren, M. Ross, and J. Gerrits, 1988, Behavior of different char components in fluidized bed combustion: a char petrography study: Fuel, v. 67, p. 426-430.Voldman, G.G., R.A. Bustos-Marún, and G.L. Albanesi, 2010, Calculation of the conodont Color Alteration Index (CAI) for complex thermal histories: International Journal of Coal Geology, v. 82, p. 45-50.Volkova, I.B., and M.V. Bogdanova, 1989, Properties of high-rank coals and dispersed organic matter of associated rocks in the Donets basin (U.S.S.R.): International Journal of Coal Geology, v. 11, p. 315-339.Volkova, I.B., and M.V. Bogdanova, 1989, Properties of high-rank coals and dispersed organic matter of associated rocks in the Donets basin (U.S.S.R.): International Journal of Coal Geology, v. 11, p. 315-339.Voltattorni, N., A. Sciarra, G. caramanna, D. Cinti, L. Pizzino, and F. Quattrocchi, 2009, Gas geochemistry of natural analogues for the studies of geological CO2 sequestration: Applied Geochemistry, v. 24, p. 1339-1346.Von der Dick, H., and W. Kalkreuth, 1986, Synchronous excitation and three-dimensional fluorescence spectroscopy applied to organic geochemistry: Organic Geochemistry, v. 10, p. 633-639.

von Schoenfeldt, H., J. Zupanik, and D. R. Wight, 2004, Unconventional drilling methods for unconventional reservoirs in the US and overseas: Tuscaloosa, Alabama, University of Alabama, College of Continuing Studies, 2004 International Coalbed Methane Symposium Proceedings, paper 0441, 10 p.Vories, K.C., 2004, The beneficial use of coal combustion by-products (CCBs) at SMCRA-regulated coal mines: Energeia, v. 15, no. 5, p. 1-3.Vorres, K. S., 1986, Mineral matter and ash in coal: American Chemical Society Symposium Series 301, 557 p.Vorres, K.S., ed., 1986, Mineral matter and ash in coal: Washington, D.C., American Chemical Society Symposium Series 301, 557 p.Vorres, K.S., ed., 1986, Mineral matter and ash in coal: Washington, D.C., American Chemical Society, ACS Symposium Series 301, 557 p.Vu, T.A.T., B. Horsfield, and R. Sykes, 2008, Influence of in-situ bitumen on the generation of gas and oil in New Zealand coals: Organic Geochemistry, v. 39, p. 1606-1619.Vu, T.T.A., B. Horsfield, N. Mahlstedt, H.J. Schenk, S.R. Kelemen, C.C. Walters, P.J. Kwiatek, and R. Sykes, 2013, The structural evolution of organic matter during maturation of coals and its impact on petroleum potential and feedstock for the deep biosphere: Organic Geochemistry, v. 62, p. 17-27.Wachowska, H., B.N. Nandi, and D.S. Montgomery, 1974, Oxidation studies on coking coal related to weathering. 4. Oxygen linkages influencing the dilatometric properties and the effect of cleavage of ether linkages: Fuel, v. 53, p. 212-219.Wachowska, H., B.N. Nandi, and D.S. Montgomery, 1974, Oxidation studies on coking coal related to weathering. 4. Oxygen linkages influencing the dilatometric properties and the effect of cleavage of ether linkages: Fuel, v. 53, p. 212-219.Wadsworth, J., R. Boyd, C. Diessel, and D. Leckie, 2003, Stratigraphic style of coal and non-marine strata in a high accommodation setting: Falher Member and Gates Formation (Lower Cretaceous), western Canada: Bulletin of Canadian Petroleum Geology, v. 51, p. 275-303.Waechter, N.B., G.L. Hampton, and J.C. Shipps, 2004, Overview of coal and shale gas measurement: field and laboratory procedures: Proceedings of 2004 International Coalbed Methane Symposium, Tuscaloosa, Alabama, University of Alabama, 17 p.Waechter, N.B., G.L. Hampton, III, S.D. Schwochow, and J.P. Seidle, 2004, Accurate gas content analysis improves coalbed gas resource estimation: World Oil, v. 225, no. 8, p. 47-51.Wagman, D., 2005, The virtue of patience: Supplement to Oil and Gas Investor, v. 25, no. 12, p. 14-20.Wagner, N.J., 1998, The effect of weathering on stored discard coals and the impact on combustion: unpublished PhD dissertation, University of Witwatersrand, South Africa.Wagner, N.J., 2007, The Abnormal Condition Analysis used to characterize weathered discard coals: International Journal of Coal Geology, v. 72, p. 177-186.Wagner, N.J., and B. Hlatshwayo, 2005, The occurrence of potentially hazardous trace elements in five Highveld coals, South Africa: International Journal of Coal Geology, v. 63, p. 228-246.Wagner, N.J., and M.T. Tlotleng, 2012, Distribution of selected trace elements in density fractionated Waterberg coals from South Africa: International Journal of Coal Geology, v. 94, p. 225-237.

Wakeley, L.D., A. Davis, R.G. Jenkins, G.D. Mitchell, and P.L. Walker, Jr., 1979, The nature of solids accumulated during solvent refining of coal: Fuel, v. 58, p. 379-385.Waldron, J.W.F., and M.C. Rygel, 2005, Role of evaporate withdrawal in the preservation of a unique coal-bearing succession: Pennsylvanian Joggins Formation, Nova Scotia: Geology, v. 33, p. 337-340.Walker, F.E., and F.E. Hartner, 1966, Forms of sulfur in U.S. coals: U.S. Bureau of Mines Information Circular 8301, 51 p.Walker, P.L., Jr., S.K. Verma, J. Rivera-Utrilla, and A. Davis, 1988, Densities, porosities and surface areas of coal macerals as measured by their interaction with gases, vapours, and liquids: Fuel, v. 67, p. 1615-1623.Walker, P.L., Jr., S.K. Verma, J. Rivera-Utrilla, and A. Davis, 1988, Densities, porosities and surface areas of coal macerals as measured by their interaction with gases, vapours, and liquids: Fuel, v. 67, p. 1615-1623.Walker, P.L., Jr., S.K. Verma, J. Rivera-Utrilla, and M.R. Khan, 1988, A direct measurement of expansion in coals and macerals induced by carbon dioxide and methanol: Fuel, v. 67, p. 719-726.Walker, R., and M. Mastalerz, 2004, Functional group and individual maceral chemistry of high volatile bituminous coals from southern Indiana: controls on coking: International Journal of Coal Geology, v. 58, p. 181-191.Walker, R., and M. Mastalerz, 2004, Functional group and individual maceral chemistry of high volatile bituminous coals from southern Indiana: controls on coking: International Journal of Coal Geology, v. 58, p. 181-191.Walker, R., and M. Mastalerz, 2004, Functional group and individual maceral chemistry of high volatile bituminous coals from southern Indiana: controls on coking: International Journal of Coal Geology, v. 58, p. 181-191.Walker, R., M. Glikson, and M. Mastalerz, 2001, Relations between coal petrology and gas content in the Upper Newlands seam, central Queensland, Australia: International Journal of Coal Geology, v. 46, p. 83-92.Walker, R., M. Mastalerz, and P. Padgett, 2001, Quality of selected coal seams from Indiana: implications for carbonization: International Journal of Coal Geology, v. 47, p. 277-286.Walker, R., M. Mastalerz, S. Brassell, E. Elswick, J.C. Hower, and A. Schimmelmann, 2007, Chemistry of thermally altered high volatile bituminous coals from southern Indiana: International Journal of Coal Geology, v. 71, p. 2-14.Walker, S., 2003, Enhanced oil recovery with CO2: World Coal, v. 12, no. 2, p. 35-36, 38-41.Walters, C.C., K. Qian, C. Wu, A.S. Mennito, and Z. Wei, 2011, Proto-solid bitumen in petroleum altered by thermochemical sulfate reduction: Organic Geochemistry, v. 42, p. 999-1006.Wan Hasiah, A., 1997, Evidence of early generation of liquid hydrocarbon from suberinite as visible under the microscope: Organic Geochemistry, v. 27, p. 591-596.

Von der Dick, H., M.G. Fowler, and W. Kalkreuth, 1989, A preliminary assessment of the hydrocarbon potential of selected coals using hydrous pyrolysis, in Contributions to Canadian coal geoscience: Geological Survey of Canada Paper 89-8, p. 115-119.

Wagner, N.J., M. Coertzen, R.H. Matjie, and J.C. van Dyk, 2008, Coal gasification, in I. Suárez-Ruiz and J.C. Crelling, eds., Applied coal petrology: the role of petrology in coal utilization: New York, Academic Press, p. 119-144.

Wang, D., X. Lu, S. Xu, and W. Hu, 2008, Comment on "Influence of a basic intrusion on the vitrinite reflectance and chemistry of the Springfield (No. 5) coal, Harrisburg, Illinois" by Stewart et al. (2005): International Journal of Coal Geology, v. 73, p. 196-199.Wang, G., T. Ren, K. Wang, and A. Zhou, 2014, Improved apparent permeability models of gas flow in coal with Klinkenberg effect: Fuel, v. 128, p. 53-61.Wang, G.X., P. Massarotto, and V. Rudolph, 2009, An improved permeability model of coal for coalbed methane recovery and CO2 geosequestration: International Journal of Coal Geology, v. 77, p. 127-136.Wang, G.X., P. Massarotto, and V. Rudolph, 2009, An improved permeability model of coal for coalbed methane recovery and CO2 geosequestration: International Journal of Coal Geology, v. 77, p. 127-136.Wang, G.X., X.R. Wei, K. wang, P. Massarotto, and V. Rudolph, 2010, Sorption-induced swelling/shrinkage and permeability of coal under stressed adsorption/desorption conditions: International Journal of Coal Geology, v. 83, p. 46-54.Wang, G.X., X.R. Wei, K. wang, P. Massarotto, and V. Rudolph, 2010, Sorption-induced swelling/shrinkage and permeability of coal under stressed adsorption/desorption conditions: International Journal of Coal Geology, v. 83, p. 46-54.Wang, G.X., Z.T. Wang, V. Rudolph, P. Massarotto, and R.J. Finley, 2007, An analytical model of the mechanical properties of bulk coal under confined stress: Fuel, v. 86, p. 1873-1884.Wang, H., B.Z. Dlugorgorski, and E.M. Kennedy, 1999, Experimental study on low-temperature oxidation of an Australian coal: Energy & Fuels, v. 13, p. 1173-1179.Wang, H., B.Z. Dlugorgorski, and E.M. Kennedy, 2003, Coal oxidation at low temperature: oxygen, consumption, oxidation products, reaction mechanism and kinetic modeling: Progress in Energy and Combustion Sciences, v. 29, p. 487-513.Wang, H., L. Shao, L. Hao, P. Zhang, I.J. Glasspool, J.R. Wheeley, P.B. Wignall, T. Yi, M. Zhang, and J. Hilton, 2011, Sedimentology and sequence stratigraphy of the Lopingian (Late Permian) coal measures in southwestern China: International Journal of Coal Geology, v. 85, p. 168-183.Wang, J., and J. Yang, 1994, Behaviour of coal pyrolysis desulfurization with microwave energy: Fuel, v. 73, p. 155.Wang, J.G., A. Kabir, J. Liu, and Z. Chen, 2012, Effects of non-Darcy flow on the performance of coal seam gas wells: International Journal of Coal Geology, v. 93, p. 62-74.Wang, J.G., J. Liu, and A. Kabir, 2013, Combined effects of directional compaction, non-Darcy flow and anisotropic swelling on coal seam gas extraction: International Journal of Coal Geology, v. 109-110, p. 1-14.Wang, K., J. Zang, G. Wang, and A. Zhou, 2014, Anisotropic permeability evolution of coal with effective stress variation and gas sorption: Model development and analysis: International Journal of Coal Geology, v. 130, p. 53-65.Wang, L., C. Wang, Y. Li, L. Zhu, and Y. Wei, 2011, Sedimentary and organic geochemical investigation of tertiary lacustrine oil shale in the central Tibetan plateau: Palaeolimnological and palaeoclimatic significances: International Journal of Coal Geology, v. 86, p. 254-265.Wang, L., K.J. Reddy, and L.C. Munn, 1994, Geochemical modeling for predicting potential solid phases controlling the dissolved molybdenum in coal overburden, Powder River Basin, WY, U.S.A.: Applied Geochemistry, v. 9, p. 37-43.Wang, N., Q. Qin, L. Chen, Y. Bai, S. Zhao, and C. Zhang, 2014, Dynamic monitoring of coalbed methane reservoirs using Super-Low Frequency electromagnetic prospecting: International Journal of Coal Geology, v. 127, p. 24-41.Wang, S., D. Elsworth, and J. Liu, 2011, Permeability evolution in fractured coal: The roles of fracture geometry and water-content: International Journal of Coal Geology, v. 87, p. 13-25.Wang, S., D. Elsworth, and J. Liu, 2011, Permeability evolution in fractured coal: The roles of fracture geometry and water-content: International Journal of Coal Geology, v. 87, p. 13-25.Wang, S., Y. Tang, H.H. Schobert, D. Jiang, X. Guo, F. Huang, Y. Guo, and Y. Su, 2014, Chemical compositional and structural characteristics of Late Permian bark coals from southern China: Fuel, v. 126, p. 116-121. (barkinite)Wang, S., Y. Tang, H.H. Schobert, G.D. Mitchell, F. Liao, and Z. Liu, 2010, A thermal behavior study of Chinese coals with high hydrogen content: International Journal of Coal Geology, v. 81, p. 37-44. (barkinite)Wang, S., Y. Tang, H.H. Schobert, Y. Guo, and Y. Su, 2013, Petrology and structural studies in liquefaction reactions of Late Permian coals from southern China: Fuel, v. 107, p. 518-524.Wang, T., W. Zhou, J. Chen, X. Xiao, Y. Li, and X. Zhao, 2014, Simulation of hydraulic fracturing using particle flow method and application in a coal mine: International Journal of Coal Geology, v. 121, p. 1-13.Wang, W., S.D. Brown, K.M. Thomas, and J.C. Crelling, 1994, Nitrogen release from a rank series of coals during temperature programmed combustion: Fuel, v. 73, p. 341-347.Wang, W., S.D. Brown, K.M. Thomas, and J.C. Crelling, 1994, Reactivity and nitrogen release from a rank series of coals during temperature programmed combustion: Fuel, v. 73, p. 341-347.Wang, W., W. Hao, S. Xu, F. Qian, S. Sang, and Y. Qin, 2014, Ash limitation of physical coal beneficiation for medium-high ash coal — A geochemistry perspective: Fuel, v. 135, p. 83-90.Wang, W., Y. Qin, C. Wei, Z. Li, Y. Guo, and Y. Zhu, 2006, Partitioning of elements and macerals during preparation of Antaibao coal: International Journal of Coal Geology, v. 68, p. 223-232.Wang, W., Y. Qin, C. Wei, Z. Li, Y. Guo, and Y. Zhu, 2006, Partitioning of elements and macerals during preparation of Antaibao coal: International Journal of Coal Geology, v. 68, p. 223-232.Wang, W., Y. Qin, D. Song, and K. Wang, 2008, Column leaching of coal and its combustion residues, Shizuishan, China: International Journal of Coal Geology, v. 75, p. 81-87.Wang, W., Y. Qin, J. Liu, J. Li, and L. Yuan, 2012, Mineral microspherules in Chinese coal and their geological and environmental significance: International Journal of Coal Geology, v. 94, p. 111-122.Wang, W., Y. Qin, S. Sang, B. Jiang, Y. Zhu, and Y. Guo, 2007, Sulfur variability and element geochemistry of the No. 11 coal seam from the Antaibao mining district, China: Fuel, v. 86, p. 777-784.Wang, W., Y. Qin, S. Sang, Y. Zhu, C. Wang, and D.J. Weiss, 2008, Geochemistry of rare earth elements in a marine influenced coal and its organic solvent extracts from the Antaibao mining district, Shanxi, China: International Journal of Coal Geology, v. 76, p. 309-317.Wang, X., 2009, Geochemistry of Late Triassic coals in the Changhe mine, Sichuan Basin, southwestern China: Evidence for authigenic lanthanide enrichment: International Journal of Coal Geology, v. 80, p. 167-174.Wang, X., M. Zhang, W. Zhang, J. Wang, Y. Zhou, X. Song, T. Li, X. Li, H. Liu, and L. Zhao, 2012, Occurrence and origins of minerals in mixed-layer illlite/smectite-rich coals of the Late Permian age from the Changxing mine, eastern Yunnan, China: International Journal of Coal Geology, v. 102, p. 26-34.Wang, X., S. Dai, C.-L. Chou, M. Zhang, J. Wang, X. Song, W. Wang, Y. Jiang, Y. Zhou, and D. Ren, 2012, Mineralogy and geochemistry of Late Permian coals from the Taoshuping mine, Yunnan Province, China: Evidences for the sources of minerals: International Journal of Coal Geology, v. 96-97, p. 49-59.Wang, X., S. Dai, C.-L. Chou, M. Zhang, J. Wang, X. Song, W. Wang, Y. Jiang, Y. Zhou, and D. Ren, 2012, Mineralogy and geochemistry of Late Permian coals from the Taoshuping mine, Yunnan Province, China: Evidences for the sources of minerals: International Journal of Coal Geology, v. 96-97, p. 49-59.Wang, X., S. Dai, Y. Sun, D. Li, W. Zhang, Y. Zhang, and Y. Luo, 2011, Modes of occurrence of fluorine in the late Paleozoic No. 6 coal from the Haerwusu surface mine, Inner Mongolia, China: Fuel, v. 90, p. 248-254.Wang, X., W. Liu, Y. Xu, U. Zheng, D. Zhang, and B. Shi, 2008, Pyrolytic simulation experiments on the role of water in natural gas generation from coal: International Journal of Coal Geology, v. 75, p. 105-112.Wang, X., Y. Jiao, L. Wu, H. Rong, X. Wang, and J. Song, 2014, Rare earth element geochemistry and fractionation in Jurassic coal from Dongsheng-Shenmu area, Ordos Basin: Fuel, v. 136, p. 233-239.Wang, Y., D. Ren, and F. Zhao, 1999, Comparative leaching experiments for trace elements in raw coal, laboratory ash, fly ash and bottom ash: International Journal of Coal Geology, v. 40, p. 103-108.Wang, Y.J., R.L. Grayson, and R.L. Sanford, eds., 1986, Use of computers in the coal industry: Boston, A.A. Balkema, 331 p.

Wang, Z., J.C. Hower, J.C. Ferm, and G.D. Wild, 1996, Characteristics of lithotype thickness and sequential association of some Kentucky coals: Organic Geochemistry, v. 24, p. 189-195.Wang, Z., J.C. Hower, J.C. Ferm, and G.D. Wild, 1996, Characteristics of lithotype thickness and sequential association of some Kentucky coals: Organic Geochemistry, v. 24, p. 189-195.Wanless, H.R., 1931, Pennsylvanian cycles in western Illinois: Illinois State Geological Survey Bulletin 60, p. 179-193.

Wanless, H.R., and F.P. Shepard, 1936, Sea level and climatic changes related to late Paleozoic cycles: Geological Society of America Bulletin, v. 47, p. 1177-1206.Wanless, H.R., and J.M. Weller, 1932, Correlation and extent of Pennsylvanian cyclothems: Geological Society of America Bulletin, v. 43, p. 1003-1016.

Waples, D.W., and R.W. Marzi, 1998, The universality of the relationship between vitrinite reflectance and transformation ratio: Organic Geochemistry, v. 28, p. 383-388.Waples, D.W., M. Ramly, and W. Leslie, 1995, Implications of vitrinite-reflectance suppression for the tectonic and thermal history of the Malay Basin: Geological Society of Malaysia Bulletin 37, p. 269-284.Ward, C.R., 1974, Isolation of mineral matter from Australian bituminous coals using hydrogen peroxide: Fuel, v. 53, p. 220-221.Ward, C.R., 1977, Mineral matter in the Springfield-Harrisburg (no. 5) coal member in the Illinois basin: Illinois State Geological Survey, Circular 498, 35 p.

Ward, C.R., 1989, Minerals in bituminous coals of the Sydney basin (Australia) and the Illinois basin (U.S.A.): International Journal of Coal Geology, v. 13, p. 455-479.Ward, C.R., 1991, Mineral matter in low-rank coals and associated strata of the Mae Moh basin, northern Thailand: International Journal of Coal Geology, v. 17, p. 69-93.Ward, C.R., 1992, Mineral matter in Triassic and Tertiary low-rank coals from south Australia: International Journal of Coal Geology, v. 20, p. 185-208.Ward, C.R., 2002, Analysis and significance of mineral matter in coal seams: International Journal of Coal Geology, v. 50, p. 135-168.Ward, C.R., A. Crouch, and D.R. Cohen, 2001, Identification of potential for methane ignition by rock friction in Australian coal mines: International Journal of Coal Geology, v. 45, p. 91-103.Ward, C.R., and J.C. Taylor, 1996, Quantitative mineralogical analysis of coals from the Callide basin, Queensland, Australia using x-ray diffractometry and normative interpretation: International Journal of Coal Geology, v. 30, p. 211-229.Ward, C.R., and L.W. Gurba, 1998, Occurrence and distribution of organic sulphur in macerals of Australian coals using electron microprobe techniques: Organic Geochemistry, v. 28, p. 635-647.Ward, C.R., and L.W. Gurba, 1999, Chemical composition of macerals in bituminous coals of the Gunnedah Basin, Australia, using electron microprobe analysis techniques: International Journal of Coal Geology, v. 39, p. 279-300.Ward, C.R., and P.J. Christie, 1994, Clays and other minerals in coal seams of the Moura-Baralaba area, Bowen basin, Australia: International Journal of Coal Geology, v. 25, p. 287-309.Ward, C.R., and S. Dai, eds., 2012, Special issue: Minerals and trace elements in coal: International Journal of Coal Geology, v. 94, 348 p.Ward, C.R., and S. Dai, eds., 2012, Special issue: Minerals and trace elements in coal: International Journal of Coal Geology, v. 94, 348 p.Ward, C.R., C.E. Matulis, J.C. Taylor, and L.S. Dale, 2001, Quantification of mineral matter in Argonne Premium Coals using interactive Rietveld-based X-ray diffraction: International Journal of Coal Geology, v. 46, p. 67-82.Ward, C.R., D. French, J. Jankowski, M. Dubikova, Z. Li, and K.W. Riley, 2009, Element mobility from fresh and long-stored acidic fly ashes associated with an Australian power station: International Journal of Coal Geology, v. 80, p. 224-236.Ward, C.R., D. French, J. Jankowski, M. Dubikova, Z. Li, and K.W. Riley, 2009, Element mobility from fresh and long-stored acidic fly ashes associated with an Australian power station: International Journal of Coal Geology, v. 80, p. 224-236.Ward, C.R., D.A. Spears, C.A. Booth, I. Staton, and L.W. Gurba, 1999, Mineral matter and trace elements in coals of the Gunnedah Basin, New South Wales, Australia: International Journal of Coal Geology, v. 40, p. 281-308.Ward, C.R., D.A. Spears, C.A. Booth, I. Staton, and L.W. Gurba, 1999, Mineral matter and trace elements in coals of the Gunnedah Basin, New South Wales, Australia: International Journal of Coal Geology, v. 40, p. 281-308.Ward, C.R., ed., 1984, Coal geology and coal technology: Boston, Blackwell Scientific Publications, 345 p.Ward, C.R., ed., 1984, Coal geology and coal technology: Palo Alto, Blackwell Scientific Publications, 345 p.Ward, C.R., J.F. Corcoran, J.D. Saxby, and H.W. Read, 1996, Occurrence of phosphorus minerals in Australian coal seams: International Journal of Coal Geology, v. 30, p. 185-210.Ward, C.R., K. Riley, and D. French, 2013, Dalway John (Dal) Swaine 1920-2013: International Journal of Coal Geology, v. 113, p. 60-62.Ward, C.R., P.R. Warbrook, and F.I. Roberts, 1989, Geochemical and mineralogical changes in a coal seam due to contact metamorphism: International Journal of Coal Geology, v. 11, p. 105-125.Ward, C.R., Z. Li, and L.W. Gurba, 2005, Variations in coal maceral chemistry with rank advance in the German Creek and Moranbah coal measures of the Bowen Basin, Australia, using electron microprobe techniques: International Journal of Coal Geology, v. 63, p. 117-129.Ward, C.R., Z. Li, and L.W. Gurba, 2005, Variations in coal maceral chemistry with rank advance in the German Creek and Moranbah coal measures of the Bowen Basin, Australia, using electron microprobe techniques: International Journal of Coal Geology, v. 63, p. 117-129.Ward, C.R., Z. Li, and L.W. Gurba, 2005, Variations in coal maceral chemistry with rank advance in the German Creek and Moranbah coal measures of the Bowen Basin, Australia, using electron microprobe techniques: International Journal of Coal Geology, v. 63, p. 117-129.

Wanless, H.R., 1952, Studies of field relations of coal beds, part 1. Studies on coalification, part 2. Widespread partings in coal beds, in Second conference on the origin and constitution of coal: Crystal Cliffs, Nova Scotia Department of Mines, p. 148-180.Wanless, H.R., 1956, Depositional basins of some widespread Pennsylvanian coal beds in the United States, in Third conference on the origin and constitution of coal: Crystal Cliffs, Nova Scotia Department of Mines, p. 94-128.Wanless, H.R., 1964, Local and regional factors in Pennsylvanian cyclic sedimentation, in D.F. Merriam, ed., Symposium on cyclic sedimentation: Kansas Geological Survey Bulletin 169, v. 2, p. 593-606.Wanless, H.R., 1969, Eustatic shifts in sea level during the deposition of late Paleozoic sediments in the central United States, in J.G. Elam and S. Chuber, eds., Cyclic sedimentation in the Permian Basin: Midland, West Texas Geological Society, Publication No. 69-56, p. 41-54.Wanless, H.R., 1969, Marine and non-marine facies of the upper Carboniferous of North America, in Sixième Congrès International de Stratigraphie et de Géologie du Carbonifère: Compte Rendu, v. 1, p. 293-336.Wanless, H.R., 1975, Distribution of Pennsylvanian coal in the United States, in E.D. McKee, E.J. Crosby, and others, Paleotectonic investigations of the Pennsylvanian System in the United States; Part II. Interpretive summary and special features of the Pennsylvanian System: U.S. Geological Survey Professional Paper 853, p. 33-47.

Wanless, H.R., J.R. Baroffio, and P.C. Trescott, 1969, Conditions of deposition of Pennsylvanian coal beds, in E.C. Dapples and M.E. Hopkins, eds., Environments of coal deposition: Geological Society of America Special Paper 114, p. 105-142.

Ward, C.R., 1984, Chemical analysis and classification of coal, in C.R. Ward, ed., Coal geology and coal technology: Boston, Blackwell Scientific Publications, p. 40-73.

Ward, C.R., Z. Li, and L.W. Gurba, 2007, Variations in elemental composition of macerals with vitrinite reflectance and organic sulphur in the Greta Coal Measures, New South Wales, Australia: International Journal of Coal Geology, v. 69, p. 205-219.Ward, C.R., Z. Li, and L.W. Gurba, 2007, Variations in elemental composition of macerals with vitrinite reflectance and organic sulphur in the Greta Coal Measures, New South Wales, Australia: International Journal of Coal Geology, v. 69, p. 205-219.Ward, C.R., Z. Li, and L.W. Gurba, 2007, Variations in elemental composition of macerals with vitrinite reflectance and organic sulphur in the Greta Coal Measures, New South Wales, Australia: International Journal of Coal Geology, v. 69, p. 205-219.Ward, C.R., Z. Li, and L.W. Gurba, 2007, Variations in elemental composition of macerals with vitrinite reflectance and organic sulphur in the Greta Coal Measures, New South Wales, Australia: International Journal of Coal Geology, v. 69, p. 205-219.Ward, C.R., Z. Li, and L.W. Gurba, 2007, Variations in elemental composition of macerals with vitrinite reflectance and organic sulphur in the Greta Coal Measures, New South Wales, Australia: International Journal of Coal Geology, v. 69, p. 205-219.Ward, C.R., Z. Li, and L.W. Gurba, 2007, Variations in elemental composition of macerals with vitrinite reflectance and organic sulphur in the Greta Coal Measures, New South Wales, Australia: International Journal of Coal Geology, v. 69, p. 205-219.Ward, C.R., Z. Li, and L.W. Gurba, 2008, Comparison of elemental composition of macerals determined by electron microprobe to whole-coal ultimate analysis data: International Journal of Coal Geology, v. 75, p. 157-165.Ward, C.R., Z. Li, and L.W. Gurba, 2008, Comparison of elemental composition of macerals determined by electron microprobe to whole-coal ultimate analysis data: International Journal of Coal Geology, v. 75, p. 157-165.Ward, C.R., Z. Li, and L.W. Gurba, 2008, Comparison of elemental composition of macerals determined by electron microprobe to whole-coal ultimate analysis data: International Journal of Coal Geology, v. 75, p. 157-165.Ward, S.D., T.A. Moore, and J. Newman, 1995, Floral assemblage of the "D" coal seam (Cretaceous): implications for banding characteristics in New Zealand coal seams: New Zealand Journal of Geology and Geophysics, v. 38, p. 283-297.Ward, S.D., T.A. Moore, and J. Newman, 1995, Floral assemblage of the "D" coal seam (Cretaceous): implications for banding characteristics in New Zealand coal seams: New Zealand Journal of Geology and Geophysics, v. 38, p. 283-297. (origin of vitrain)

Warwick, P.D., F.C. Breland, Jr., and P.C. Hackley, 2008, Biogenic origin of coalbed gas in the northern Gulf of Mexico Coastal Plain, U.S.A.: International Journal of Coal Geology, v. 76, p.119-137.

Warwick, P.D., J.R. Sanfilipo, C.E. Barker, and L.E. Morris, 1999, Coal-bed methane in the Gulf Coastal Plain; a new frontier? (abstract): GSA Abstracts with Programs, v. 31, no. 7, p. 386.Washburn, K.E., and J.E. Bidwell, 2013, Multivariate analysis of ATR-FTIR spectra for assessment of oil shale organic geochemical properties: Organic Geochemistry, v. 63, p. 1-7.Watkins, E., 2010, Jordan to exploit shale deposits under accord with Enefit: Oil & Gas Journal, v. 108.28, p. 70-71.Watson, S.W., 1976, The sedimentary geochemistry of the Moffat shales: a carbonaceous sequence in the southern uplands of Scotland: Fife, University of St. Andrews, unpublished PhD thesis.Watson, W.D., L.F. Ruppert, L.J. Bragg, and S.J. Tewalt, 2001, A geostatistical approach to predicting sulfur content in the Pittsburgh coal bed: International Journal of Coal Geology, v. 48, p. 1-22.Watson, W.D., L.F. Ruppert, S.J. Tewalt, and L.J. Bragg, 2001, The Upper Pennsylvanian Pittsburgh coal bed: resources and mine models: Natural Resources Research, v. 10, p. 21-34.Wavrek, D.A., D.M. Jarvie, and J.D. Burgess, 1999, Characterization of solid reservoir bitumen: insights to formation mechanism, timing, and correlation (abstract): TSOP Abstracts and Program, v. 16, p. 7-10.Wdowin, M., R. Tarkowski, and W. Franus, 2014, Determination of changes in the reservoir and cap rocks of the Chabowo Anticline caused by CO2-brine-rock interactions: International Journal of Coal Geology, v. 130, p. 79-88.

Webber, M.E., 2009, Coal-to-liquids: the good, the bad and the ugly: Earth, v. 54, no. 4, p. 44-51.Webber, T., J. felipe Coimbra Leite Costa, and P. Salvadoretti, 2013, Using borehole geophysical data as soft information in indicator kriging for coal quality estimation: International Journal of Coal Geology, v. 112, p. 67-75.

Weber, M., T.H. Wilson, B. Akwari, A.W. Wells, and G. Koperna, 2012, Impact of geological complexity of the Fruitland Formation on combined CO2 enhanced recovery/sequestration at San Juan Basin pilot site: International Journal of Coal Geology, v. 104, p. 46-58.Weber, M., T.H. Wilson, B. Akwari, A.W. Wells, and G. Koperna, 2012, Impact of geological complexity of the Fruitland Formation on combined CO2 enhanced recovery/sequestration at San Juan Basin pilot site: International Journal of Coal Geology, v. 104, p. 46-58.Weber, P.A., W.A. Stewart, W.M. Skinner, C.G. Weisener, J.E. Thomas, and R.St.C. Smart, 2004, Geochemical effects of oxidation products and framboidal pyrite oxidation in acid mine drainage prediction techniques: Applied Geochemistry, v. 19, p. 1953-1974.Weeden, S., 2013, Queensland LNG projects lead CBM developments worldwide: Hart’s E&P, v. 86, no. 12, p. 68-73.Wei, C., Y. Qin, G.G.X. Wang, X. Fu, and Z. Zhang, 2010, Numerical simulation of coalbed methane generation, dissipation and retention in SE edge of Ordos Basin, China: International Journal of Coal Geology, v. 82, p. 147-159.Wei, C., Y. Qin, G.G.X. Wang, X. Fu, B. Jiang, and Z. Zhang, 2007, Simulation study on evolution of coalbed methane reservoir in Qinshui Basin, China: International Journal of Coal Geology, v. 72, p. 53-69.Wei, L., Z. Zhihuan, Y. Yongcai, H. Liguo, and S. Minghua, 2006, Constraining the hydrocarbon expulsion history of the coals in Qinshui Basin, North China, from the analysis of fluid inclusions: Journal of Geochemical Exploration, v. 89, p. 222-226.Wei, X., P. Massarotto, G. Wang, V. Rudolph, and S.D. Golding, 2010, CO2 sequestration in coals and enhanced coalbed methane recovery: New numerical approach: Fuel, v. 89, p. 1110-1118.Wei, X., P. Massarotto, G. Wang, V. Rudolph, and S.D. Golding, 2010, CO2 sequestration in coals and enhanced coalbed methane recovery: New numerical approach: Fuel, v. 89, p. 1110-1118.Wei, X.-Y., X.-H. Wang, Z.-H. Zong, Z.-H. Ni, L.-F. Zhang, Y.-F. Ji, K.-C. Xie, C.W. Lee, Z.-X. Liu, N.-B. Chu, and J.-Y. Cui, 2004, Identification of organochlorines and organobromines in coals: Fuel, v. 83, p. 2435-2438.

Warwick, P.D., 2005, Coal systems analysis: a new approach to the understanding of coal formation, coal quality and environmental considerations, and coal as a source rock for hydrocarbons, in P.D. Warwick, ed., Coal systems analysis: Geological Society of America Special Paper 387, p. 1-8.Warwick, P.D., 2005, Coal systems analysis: a new approach to the understanding of coal formation, coal quality and environmental considerations, and coal as a source rock for hydrocarbons, in P.D. Warwick, ed., Coal systems analysis: Geological Society of America Special Paper 387, p. 1-8.Warwick, P.D., C.E. Barker, and J.R. SanFilipo, 2002, Preliminary evaluation of the coalbed methane potential of the Gulf Coastal Plain, USA and Mexico, in S.D. Schwochow and V.F. Nuccio, eds., Coalbed methane of North America, II: Rocky Mountain Association of Geologists, p. 99-107.Warwick, P.D., C.E. Barker, J.R. SanFilipo, and L.E. Morris, 2000, Preliminary results from coal-bed methane drilling in Panola County, Texas: U.S. Geological Survey Open-File Report 00-0048, 30 p. (see http://pubs.usgs.gov/openfile/of00-048/)Warwick, P.D., C.E. Barker, J.R. SanFilipo, and L.R.H. Biewick, 2000, Preliminary evaluation of the coalbed methane resources of the Gulf Coastal Plain: U.S. Geological Survey, Open-File Report 00-0143. (see http://pubs.usgs.gov/openfile/of00-143/)Warwick, P.D., F.C. Breland, Jr., A.C. Clark, and J.C. Willett, 2004, Preliminary results from coal-bed methane drilling in Ouachita Parish, Louisiana: U.S. Geological Survey Open File Report 2004-1239, 4 p. (http://pubs.usgs.gov/of/2004/1239/2004-1239.pdf)

Warwick, P.D., F.C. Breland, Jr., M.E. Ratchford, and P.C. Hackley, 2004, Coal gas resource potential of Cretaceous and Paleogene coals of the Gulf of Mexico Coastal Plain, in P.D. Warwick, ed., Selected presentations on coal-bed gas in the eastern United States: U.S. Geological Survey Open-File Report 2004-1273, p. 1-25. (http://pubs.usgs.gov/of/2004/1273/2004-1273Warwick.pdf)

Weatherl, B.D., 2005, Using traditional completion practices to optimize horizontal CBM wells in the Hartshorne coal, Arkoma Basin, Oklahoma (abstract), in B.J. Cardott, ed., Unconventional energy resources in the southern Midcontinent, 2004 symposium: Oklahoma Geological Survey Circular 110, p. 115.

Weber, M., 1982, Well-log geophysics for coal measures, in C.W. Mallett, ed., Coal resources: origin, exploration, and utilization in Australia, Proceedings: Geological Society of Australia Coal Group, Symposium, p. 354-363.

Wei, Z., J.M. Moldowan, D.M. Jarvie, and R. Hill, 2006, The fate of diamondoids in coals and sedimentary rocks: Geology, v. 34, p. 1013-1016.

Weishauptová, Z., and I. Sýkorová, 2011, Dependence of carbon dioxide sorption on the petrographic composition of bituminous coals from the Czech part of the Upper Silesian Basin, Czech Republic: Fuel, v. 90, p. 312-323.

Weishauptová, Z., J. Medek, and L. Ková, 2004, Bond forms of methane in porous system of coal II: Fuel, v. 83, p. 1759-1764.Weith, J.D., 2004, Is oil shale the answer? (letter to editor): Oil & Gas Journal, v. 102.36, p. 10, 12.Welch, J., 2009, Reverse osmosis treatment of CBM produced water continues to evolve: Oil & Gas Journal, v. 107.37, p. 45-50.Weller, J.M., 1930, Cyclical sedimentation of the Pennsylvanian Period and its significance: Journal of Geology, v. 38, p. 97-135.Weller, J.M., 1931, The conception of cyclical sedimentation during the Pennsylvanian Period: Illinois State Geological Survey Bulletin 60, p. 163-177.Weller, J.M., 1956, Argument for diastrophic control of late Paleozoic cyclothems: AAPG Bulletin, v. 40, p. 17-50.

Weller, J.M., 1957, Paleoecology of the Pennsylvanian Period in Illinois and adjacent states: Geological Society of America Memoir 67, p. 325-364.

Wells, A.W., J.R. Diehl, G. Bromhal, B.R. Strazisar, T.H. Wilson, and C.M. White, 2007, The use of tracers to assess leakage from sequestration of CO2 in a depleted oil reservoir, New Mexico, USA: Applied Geochemistry, v. 22, p. 996-1016.Wen, C.-Y., E.S. Lee, and S. Dutta, 1979, Coal conversion technology: Reading, MA, Addison-Wesley Publishing Co., Energy Science and Technology 2, 586 p.Wen, G., W. Liu, C. Xu, L. Li, and X. Liu, 2011, Automated hydraulic correction technology for CBM horizontal wellbore: International Journal of Coal Geology, v. 85, p. 191-201.

Wendell, J.H., Jr., 2003, Coalbed methane: smaller operations and economic analysis can improve potential profit (abstract): AAPG Mid-Continent Section Meeting, Official Program Book, p. 45.

Weng, R.-F., W.-L. Huang, C.-L. Kuo, and S. Inan, 2002, Oil generation and expulsion from coals and source rocks using diamond anvil cell pyrolysis (abstract): TSOP Annual Meeting, abstract B3.2.3.Weng, R.-F., W.-L. Huang, C.-L. Kuo, and S. Inan, 2003, Characterization of oil generation and expulsion from coals and source rocks using diamond anvil cell pyrolysis: Organic Geochemistry, v. 34, p. 771-787.

Wenger, L.M., and D.R. Baker, 1987, Variations in vitrinite reflectance with organic facies - examples from Pennsylvanian cyclothems of the Midcontinent, U.S.A.: Organic Geochemistry, v. 11, p. 411-416.Wenger, L.M., and D.R. Baker, 1987, Variations in vitrinite reflectance with organic facies -- examples from Pennsylvanian cyclothems of the Midcontinent, U.S.A.: Organic Geochemistry, v. 11, p. 411-416.Wenger, L.M., and D.R. Baker, 1987, Variations in vitrinite reflectance with organic facies — examples from Pennsylvanian cyclothems of the Midcontinent, U.S.A.: Organic Geochemistry, v. 11, p. 411-416.Weniger, P., J. Francu, P. Hemza, and B.M. Krooss, 2012, Investigations on the methane and carbon dioxide sorption capacity of coals from the SW Upper Silesian coal basin, Czech Republic: International Journal of Coal Geology, v. 93, p. 23-39.Weniger, P., J. Francu, P. Hemza, and B.M. Krooss, 2012, Investigations on the methane and carbon dioxide sorption capacity of coals from the SW Upper Silesian coal basin, Czech Republic: International Journal of Coal Geology, v. 93, p. 23-39.Weniger, P., W. Kalkreuth, A. Busch, and B.M. Krooss, 2010, High-pressure methane and carbon dioxide sorption on coal and shale samples from the Paraná Basin, Brazil: International Journal of Coal Geology, v. 84, p. 190-205.Weniger, P., W. Kalkreuth, A. Busch, and B.M. Krooss, 2010, High-pressure methane and carbon dioxide sorption on coal and shale samples from the Paraná Basin, Brazil: International Journal of Coal Geology, v. 84, p. 190-205.Weniger, P., W. Kalkreuth, A. Busch, and B.M. Krooss, 2010, High-pressure methane and carbon dioxide sorption on coal and shale samples from the Paraná Basin, Brazil: International Journal of Coal Geology, v. 84, p. 190-205.Wert, C., Y. Ge, B.H. Tseng, and K.C. Hsieh, 1988, Analysis of organic sulfur in coal by use of transmission electron microscopy: Journal of Coal Quality, v. 7, p. 118-121.Wertz, D.L., C.B. Smithhart, M.L. Steele, and S. Caston, 1993, X-ray characterization of resides from the Wilsonville, AL, two-stage direct liquefaction facility. I. XRD and XRF analysis of the Illinois No. 6 resids from run no. 257: Journal of Coal Quality, v. 12, p. 36-41.Wessling, S., C. Kuenzer, W. Kessels, and M.W. Wuttke, 2008, Numerical modeling for analyzing thermal surface anomalies induced by underground coal fires: International Journal of Coal Geology, v. 74, p. 175-184.Westgate, L.M., and T.F. Anderson, 1984, Isotopic evidence for the origin of sulfur in the Herrin (No. 6) coal member of Illinois: International Journal of Coal Geology, v. 4, p. 1-20.Westrich, H.R., J. Lorenz, S. Cooper, and others, 2002, Sequestration of CO2 in a depleted oil reservoir—An overview: Journal of Energy and Environmental Research, v. 2, p. 64-74.Wetzel, W., and G. Collin, 1999, Asphalt, bitumen, tar – their importance in cultural and technical history (in German): Erdöl Erdgas Kohle, v. 115, no. 10, p. 488-495.

Whateley, M.K.G., and D.A. Spears, eds., 1995, European coal geology: London, The Geological Society Special Publication 82, 331 p.Wheat, R.W., 1999, Coalbed methane potential, core and pilot program, Illinois basin (abstract): AAPG Bulletin, v. 83, p. 1374.Wheaton, J., and T. Donato, 2004, Coalbed-methane basics: Powder River Basin, Montana: Montana Bureau of Mines and Geology, Information Pamphlet 5, 20 p.

Weibel, C.P., 2002, Evolution of the boundaries used to map Pennsylvanian cyclothemic sequences in Illinois, USA, in L.V. Hills, C.M. Henderson, and E.W. Bamber, eds., Carboniferous and Permian of the World: Canadian Society of Petroleum Geologists Memoir 19, p. 239-251.

Weishauptová, Z., J. Medek, and J. Němec, 1999, Decrease of desorption intensity of coalbed methane due to hydraulic fracturing, in M. Mastalerz, M. Glikson, and S.D. Golding, eds., Coalbed methane: scientific, environmental and economic evaluation: Boston, Kluwer Academic Publishers, p. 385-393.

Weller, J.M., 1956, Patterns in Pennsylvanian cyclothems, in Third conference on the origin and constitution of coal: Crystal Cliffs, Nova Scotia Department of Mines, p. 129-171.

Weller, J.M., 1964, Development of the concept and interpretation of cyclic sedimentation, in D.F. Merriam, ed., Symposium on cyclic sedimentation: Kansas Geological Survey Bulletin 169, v. 2, p. 607-621.

Wendell, J.H., Jr., 2001, Arkoma basin coalbed-methane potential and practices, in B.J. Cardott, compiler, Oklahoma coalbed-methane workshop 2001: OGS Open-File Report 2-2001, p. 119-139.Wendell, J.H., Jr., 2002, Arkoma Basin coalbed methane—potential and practices, in B.J. Cardott, ed., Revisiting old and assessing new petroleum plays in the southern Midcontinent, 2001 symposium: OGS Circular 107, p. 87-100.

Wendell, J.H., Jr., 2005, Coalbed methane: what makes for economic success in the Arkoma Basin—methods and economics, in B.J. Cardott, ed., Unconventional energy resources in the southern Midcontinent, 2004 symposium: Oklahoma Geological Survey Circular 110, p. 107-114.

Wenger, L.M., and D.R. Baker, 1986, Variations in organic geochemistry of anoxic-oxic black shale-carbonate sequences in the Pennsylvanian of the Midcontinent, U.S.A., in Advances in Organic Geochemistry 1985: Organic Geochemistry, v. 10, p. 85-92.

Whateley, M.K.G., 2002, Measuring, understanding and visualizing coal characteristics—innovations in coal geology for the 21 st century: International Journal of Coal Geology, v. 50, p. 303-315.

Wheeler, H.E., and H.H. Murray, 1957, Base-level control patterns in cyclothemic sedimentation: AAPG Bulletin, v. 41, p. 1985-2011.Whelan, J.F., J.C. Cobb, and R.O. Rye, 1988, Stable isotope geochemistry of -Sphalerite and other mineral matter in coal beds of the Illinois and Forest City basins: Economic Geology, v. 83, p. 990-1007

White, C.M., B.R. Strazisar, E.J. Granite, J.S. Hoffman, and H.W. Pennline, 2003, Separation and capture of CO2 from large stationary sources and sequestration in geological formation—coalbeds and deep saline aquifers: Journal of the Air and Waste Management Association, v. 53, p. 645-715.White, C.M., D.H. Smith, K.L. Jones, A.L. Goodman, S.A. Jikich, R.B. LaCount, S.B. DuBose, E. Ozdemir, B.I. Morsi, and K.T. Schroeder, 2005, Sequestration of carbon dioxide in coal with enhanced coalbed methane recovery—a review: Energy & Fuel, v. 19, p. 659-724.White, C.M., D.H. Smith, K.L. Jones, A.L. Goodman, S.A. Jikich, R.B. LaCount, S.B. DuBose, E. Ozdemir, B.I. Morsi, and K.T. Schroeder, 2005, Sequestration of carbon dioxide in coal with enhanced coalbed methane recovery—a review: Energy & Fuel, v. 19, p. 659-724.

White, D., 1909, Occurrence of resin in Paleozoic coals: Science, v. 29, p. 945.White, D., 1914, Resins in Paleozoic plants and in coals of high rank: U.S. Geological Survey Professional Paper 85-E, p. 65-83.White, D., 1925, Environmental conditions of deposition of coal: American Institute of Mining and Metallurgical Engineers Transactions, v. 71, p. 3-34.White, D., 1929, Description of fossil plants found in some "mother rocks" of petroleum from northern Alaska: American Association of Petroleum Geologists Bulletin, v. 13, p. 841-848. (algal coals)

White, D., 1933, Role of water conditions in the formation and differentiation of common (banded) coals: Economic Geology, v. 28, p. 556-570.White, D., and R. Thiessen, 1913, The origin of coal: U.S. Bureau of Mines Bulletin 38, 390 p.White, D., R. Thiessen, and C.A. Davis, 1913, The origin of coal: U.S. Bureau of Mines Bulletin 38, 390 p.White, D.J., G. Burrowes, T. Davis, Z. Hijnal, K. Hirsche, I. Hutcheon, E. Majer, B. Rostron, and S. Whittaker, 2004, Greenhouse gas sequestration in abandoned oil reservoirs: The International Energy Agency Weyburn pilot project: GSA Today, v. 14, no. 7, p. 4-10.White, I.C., 1899, Origin of grahamite: Geological Society of America Bulletin, v. 10, p. 277-284.White, J.C., M.R. Gibling, and W.D. Kalkreuth, 1994, The Backpit seam, Sydney Mies Formation, Nova Scotia: a record of peat accumulation and drowning in a Westphalian coastal mire: Palaeogeography, Palaeoclimatology, Palaeoecology, v. 106, p. 223-239.Whitehurst, D.D., ed., 1980, Coal liquefaction fundamentals: Washington, D.C., American Chemical Society, Symposium Series 139, 411 p.Whitehurst, D.D., T.O. Mitchell, and M. Farcasin, 1980, Coal liquefaction: New York, Academic Press, 378 p.Whitham, A.G., and J.E.A. Marshall, 1988, Syn-depositional deformation in a Cretaceous succession, James Ross Island, Antarctica. Evidence from vitrinite reflectivity: Geological Magazine, v. 125, p. 583-591.Whittles, D.N., I.S. Lowndes, S.W. Kingman, C. Yates, and S. Jobling, 2007, The stability of methane capture boreholes around a long wall coal panel: International Journal of Coal Geology, v. 71, p. 313-328.

Wicks, D.E., and M.D. Zuber, 1989, A strategy for coalbed methane production development part II: reservoir characterization: Tuscaloosa, Alabama, Proceedings of the 1989 Coalbed Methane Symposium, paper 8912, p. 11-18.Widodo, S., W. Oschmann, A. Bechtel, R.F. Sachsenhofer, K. Anggayana, and W. Puettmann, 2010, Distribution of sulfur and pyrite in coal seams from Kutai Basin (East Kalimantan, Indonesia): implications for paleoenvironmental conditions: International Journal of Coal Geology, v. 81, p. 151-162.Widodo, S., W. Oschmann, A. Bechtel, R.F. Sachsenhofer, K. Anggayana, and W. Puettmann, 2010, Distribution of sulfur and pyrite in coal seams from Kutai Basin (East Kalimantan, Indonesia): implications for paleoenvironmental conditions: International Journal of Coal Geology, v. 81, p. 151-162.Widodo, S., W. Oschmann, A. Bechtel, R.F. Sachsenhofer, K. Anggayana, and W. Puettmann, 2010, Distribution of sulfur and pyrite in coal seams from Kutai Basin (East Kalimantan, Indonesia): implications for paleoenvironmental conditions: International Journal of Coal Geology, v. 81, p. 151-162.Wiese, R.G., Jr., and W.S. Fyfe, 1986, Occurrences of iron sulfides in Ohio coals: International Journal of Coal Geology, v. 6, p. 251-276.Wigand, M., J.W. Carey, H. Schütt, E. Epangenberg, and J. Erzinger, 2008, Geochemical effects of CO2 sequestration in sandstones under simulated in situ conditions of deep saline aquifers: Applied Geochemistry, v. 23, p. 2735-2745.Wight, D., 2004, Horizontal drilling adds value in CBG: The American Oil & Gas Reporter, v. 47, no. 5, p. 80-82, 85.Wightman, W.G., D.B. Scott, F.S. Medioli, and M.R. Gibling, 1993, Carboniferous marsh foraminifera from coal-bearing strata at the Sydney Basin, Nova Scotia: a new tool for identifying paralic coal-forming environments: Geology, v. 21, p. 631-634.Wilcox, J., 2012, Carbon capture: New York, Springer Science.Wilcox, J., E. Rupp, S.C. Ying, D.-H. Lim, A.S. Negreira, A. Kirchofer, F. Feng, and K. Lee, 2012, Mercury adsorption and oxidation in coal combustion and gasification processes: International Journal of Coal Geology, v. 90-91, p. 4-20.Wilcox, J., E. Rupp, S.C. Ying, D.-H. Lim, A.S. Negreira, A. Kirchofer, F. Feng, and K. Lee, 2012, Mercury adsorption and oxidation in coal combustion and gasification processes: International Journal of Coal Geology, v. 90-91, p. 4-20.Wilcox, J., E. Rupp, S.C. Ying, D.-H. Lim, A.S. Negreira, A. Kirchofer, F. Feng, and K. Lee, 2012, Mercury adsorption and oxidation in coal combustion and gasification processes: International Journal of Coal Geology, v. 90-91, p. 4-20.Wild, G.D., K.W. Kuehn, and J.C. Hower, 2000, Assessment of compositional variation in duplicate samples of pelletized coal: International Journal of Coal Geology, v. 42, p. 231-240.Wildman, R.A., R.A. Berner, S.T. Petsch, E.W. Bolton, J.O. Eckert, U. Mok, and J.B. Evans, 2004, The weathering of sedimentary organic matter as a control on atmospheric O2: I. Analysis of black shale: American Journal of Science, v. 304, p. 234-249.Wilhelms, A., S.R. Larter, and D. Leythaeuser, 1991, Influence of bitumen-2 on Rock-Eval pyrolysis: Organic Geochemistry, v. 17, p. 351-354.

Wilkins, R.W.T., and S.C. George, 2002, Coal as a source rock for oil: a review: International Journal of Coal Geology, v. 50, p. 317-361.

Whelan, J.K., and C.L. Thompson-Rizer, 1993, Chemical methods for assessing kerogen and protokerogen types and maturity, in M.H. Engel and S.A. Macko, eds., Organic geochemistry: New York, Plenum Press, p. 289-353.Whelan, J.K., and C.L. Thompson-Rizer, 1993, Chemical methods for assessing kerogen and protokerogen types and maturity, in M.H. Engel and S.A. Macko, eds., Organic geochemistry: principles and applications: New York, Plenum Press, p. 289-353.

White, C.M., L.J. Douglas, R.R. Anderson, C.E. Schmidt, and R.J. Gray, 1990, Organosulfur constituents in Rasa coal, in W.L. Orr and C.M. White, eds., Geochemistry of sulfur in fossil fuels: Washington, D.C., American Chemical Society Symposium Series 429, p. 261-286.

White, D., 1931, Climatic implications of Pennsylvanian flora, in Papers presented at the Quarter Centennial Celebration of the Illinois State Geological Survey: Illinois State Geological Survey Bulletin 60, p. 271-281.

Wicander, R., C.B. Foster, and J.D. Reed, 1996, Gloeocapsomorpha, in J. Jansonius and D.C. McGregor, eds., Palynology: principles and applications: American Association of Stratigraphic Palynologists, v. 1, p. 215-225.

Wilk, P., and K. Bratek, 1995, The aspects of microscopic studies as exemplified by the macroporous structure of cokes from bituminous coal range, in C. Snape, ed., Composition, geochemistry, and conversion of oil shales: Boston, Kluwer Academic Publishers, NATO ASI Series C, Mathematical and Physical Sciences, v. 455, p. 485-492.

Wilkins, R.W.T., and S.C. George, 2002, Coal as a source rock for oil: a review: International Journal of Coal Geology, v. 50, p. 317-361.Wilkins, R.W.T., C.F.K. Diessel, and C.P. Buckingham, 2002, Comparison of two petrographic methods for determining the degree of anomalous vitrinite reflectance: International Journal of Coal Geology, v. 52, p. 45-62.Wilkins, R.W.T., C.F.K. Diessel, and C.P. Buckingham, 2002, Comparison of two petrographic methods for determining the degree of anomalous vitrinite reflectance: International Journal of Coal Geology, v. 52, p. 45-62.Wilkins, R.W.T., C.F.K. Diessel, and C.P. Buckingham, 2002, Comparison of two petrographic methods for determining the degree of anomalous vitrinite reflectance: International Journal of Coal Geology, v. 52, p. 45-62.Wilkins, R.W.T., C.F.K. Diessel, and C.P. Buckingham, 2002, Comparison of two petrographic methods for determining the degree of anomalous vitrinite reflectance: International Journal of Coal Geology, v. 52, p. 45-62. (see p. 57-58 for discussion of oxidation.)Wilkins, R.W.T., C.P. Buckingham, N. Sherwood, N.J. Russell, M. Faiz, and J. Kurusingal, 1998, The current status of the FAMM thermal maturity technique for petroleum exploration in Australia: The Australian Petroleum Exploration Association (APEA) Journal, v. 38, p. 421-443.Wilkins, R.W.T., C.P. Buckingham, N. Sherwood, N.J. Russell, M. Faiz, and J. Kurusingal, 1998, The current status of the FAMM thermal maturity technique for petroleum exploration in Australia: The Australian Petroleum Exploration Association (APEA) Journal, v. 38, p. 421-443.Wilkins, R.W.T., J.R. Wilmshurst, G. Hladky, M.V. Ellacott, and C.P. Buckingham, 1992, The suppression of vitrinite reflectance in some North West Shelf wells: Barrow-1, Jupiter-1 and Flamingo-1: APEA Journal, v. 32, part 1, p. 300-312.Wilkins, R.W.T., J.R. Wilmshurst, G. Hladky, M.V. Ellacott, and C.P. Buckingham, 1992, The suppression of vitrinite reflectance in some North West Shelf wells: Barrow-1, Jupiter-1 and Flamingo-1: The APEA Journal, v. 32, pt. 1, p. 300-312.Wilkins, R.W.T., J.R. Wilmshurst, G. Hladky, M.V. Ellacott, and C.P. Buckingham, 1994, Should fluorescence alteration replace vitrinite reflectance as a major tool for thermal maturity determination in oil exploration?: Organic Geochemistry, v. 22, p. 191-209.Wilkins, R.W.T., J.R. Wilmshurst, G. Hladky, M.V. Ellacott, and C.P. Buckingham, 1994, Should fluorescence alteration replace vitrinite reflectance as a major tool for thermal maturity determination in oil exploration?: Organic Geochemistry, v. 22, p. 191-209.Wilkins, R.W.T., J.R. Wilmshurst, G. Hladky, M.V. Ellacott, and C.P. Buckingham, 1994, Should fluorescence alteration replace vitrinite reflectance as a major tool for thermal maturity determination in oil exploration?: Organic Geochemistry, v. 22, p. 191-209.Wilkins, R.W.T., J.R. Wilmshurst, N.J. Russell, G. Hladky, M.V. Ellacott, and C. Buckingham, 1992, Fluorescence alteration and the suppression of vitrinite reflectance: Organic Geochemistry, v. 18, p. 629-640.Wilkins, R.W.T., J.R. Wilmshurst, N.J. Russell, G. Hladky, M.V. Ellacott, and C. Buckingham, 1992, Fluorescence alteration and the suppression of vitrinite reflectance: Organic Geochemistry, v. 18, p. 629-640.Wilkins, R.W.T., J.R. Wilmshurst, N.J. Russell, G. Hladky, M.V. Ellacott, and C. Buckingham, 1992, Fluorescence alteration and the suppression of vitrinite reflectance: Organic Geochemistry, v. 18, p. 629-640.Wilkins, R.W.T., M.V. Ellacott, J.R. Wilmshurst, and C. Buckingham, 1994, The suppression of inertinite reflectance: Organic Geochemistry, v. 21, p. 871-875.Wilkins, R.W.T., R. Boudou, N. Sherwood, and X. Xiao, 2014, Thermal maturity evaluation from inertinites by Raman spectroscopy: The ‘RaMM’ technique: International Journal of Coal Geology, v. 128-129, p. 143-152.Wilkinson, B.H., G.K. Merrill, and S.J. Kivett, 2003, Stratal order in Pennsylvanian cyclothems: Geological Society of America Bulletin, v. 115, p. 1068-1087. (discussion and reply in v. 116, p. 1545-1550)Wilkinson, H.C., 1984, Correspondance between the composition and plastic properties of British coals and the structural properties and reactivity of the corresponding cokes: Fuel, v. 63, p. 101-108.Wilkinson, R., 2011, Eastern Australian coalbed methane supply rivals western offshore conventional resource: Oil & Gas Journal, v. 109.12, p. 56-64.Wilks, K.R., M. Mastalerz, J.V. Ross, and R.M. Bustin, 1993, The effect of experimental deformation on the graphitization of Pennsylvania anthracite: International Journal of Coal Geology, v. 24, p. 347-369.

Willard, D.A., M.A. DiMichele, D.L. Eggert, J.C. Hower, C.B. Rexroad, and A.C. Scott, 1995, Paleoecology of the Springfield coal member (Desmoinesian, Illinois Basin) near the Leslie Cemetery paleochannel, southwestern Indiana: International Journal of Coal Geology, v. 27, p. 59-98.Willard, D.A., T.L. Phillips, A.D. Lesnikowska, and W.A. DiMichele, 2007, Paleoecology of the Late Pennsylvanian-age Calhoun coal bed and implications for long-term dynamics of wetland ecosystems: International Journal of Coal Geology, v. 69, p. 21-54.Willenbrink, B., 2003, Degassing developments: World Coal, v. 12, no. 3, p. 51-52, 54.Williams, A., M. Pourkashanian, J.M. Jones, and N. Skorupska, 2000, Combustion and gasification of coal: New York, Taylor & Francis, Applied Energy Technology Series, 263 p.Williams, A., M. Pourkashanian, J.M. Jones, and N. Skorupska, 2000, Combustion and gasification of coal: New York, Taylor & Francis, Applied Energy Technology Series, 263 p.Williams, B., 2003, Heavy hydrocarbons playing key role in peak-oil debate, future energy supply: Oil & Gas Journal, v. 101.29, p. 20-27.Williams, E.G., and M.L. Keith, 1963, Relationship between sulfur in coals and the occurrence of marine roof beds: Economic Geology, v. 58, p. 720-729.Williams, L.B., and R.L. Hervig, 2004, Boron isotope composition of coals: a potential tracer of organic contaminated fluids: Applied Geochemistry, v. 19, p. 1625-1636.Williams, P., 2002, Coalbed methane in the Cherokee Basin: Oil and Gas Investor, v. 22, no. 2, p. 49-51.Williams, P., 2004, Alberta’s CBM: Oil and Gas Investor, v. 24, no. 6, p. C-9.Williams, P., 2004, Coalbed methane: Oil and Gas Investor, v. 24, no. 6, p. 30-38.Williams, P., 2004, More CBM basins to watch: Oil and Gas Investor, v. 24, no. 6, p. 107.Williams, P., 2005, China: Oil and Gas Investor, v. 25, no. 6, p. 32-45. (China CBM opportunities, p. 38-39)Williams, P., 2005, Hartshorne horizontals: Oil and Gas Investor, v. 25, no. 5, p. 51-53.Williams, P., 2005, Investing in CBM projects: Oil and Gas Investor, v. 25, no. 6, p. 79.Williams, P., 2005, Western U.S. oil shale: Oil and Gas Investor, v. 25, no. 11, p. 69.Williams, P., 2006, Alabama hat trick: Oil and Gas Investor, v. 26, no. 3, p. 67-68.Williams, P., 2006, Virginia’s CBM play: Oil and Gas Investor, v. 26, no. 3, p. 97.Williams, P., 2006, Western Canadian CBM: Oil and Gas Investor, v. 26, no. 9, p. 42-51.

Willard, D.A., 1993, Vegetational patterns in the Springfield coal bed (Middle Pennsylvanian, Illinois basin): comparison of miospore and coal-ball records, in J.C. Cobb and C.B. Cecil, eds., Modern and ancient coal-forming environments: GSA Special Paper 286, p. 139-152.

Williams, P., 2007, Green River oil shale: Oil and Gas Investor, v. 27, no. 7, p. 73.Williams, P., 2007, Powder River gas factory: Oil and Gas Investor, v. 27, no. 10, p. 149.Williams, P., 2007, Slater Dome: Oil & Gas Investor, v. 27, no. 12, p. 75.Williams, P., 2008, Green oil: Oil and Gas Investor, v. 28, no. 10, p. 42-52.Williams, P., 2008, Illinois Basin CBM: Oil and Gas Investor, v. 28, no. 1, p. 127.Williams, P., 2010, Australian CBM on the verge: Oil and Gas Investor, v. 30, no. 11, p. 87.Williams, S.H., E.T. Burden, and P.K. Mukhopadhyay, 1998, Thermal maturity and burial history of Paleozoic rocks in western Newfoundland: Canadian Journal of Earth Science, v. 35, p. 1307-1322. (graptolite reflectance)Williams, V.E., and C.A. Ross, 1979, Depositional setting and coal petrology of Tulameen coalfield, south-central British Columbia: AAPG Bulletin, v. 63, p. 2058-2069.Williams, V.E., and R.J. Witmer, 1989, Palynological kerogen: classification and geological applications (abstract): AASP, Palynology, v. 13, p. 287.Williamson, D.R., 1965, Oil shales part 5—Oil shale retorts: Colorado School of Mines Research Institute, Mineral Industries Bulletin, v. 8, no. 2.Willyard, C., 2009, Capturing carbon from coal plants: is it feasible?: Earth, v. 54, no. 4, p. 36-43.

Wilson, B., 2014, Geologic and baseline groundwater evidence for naturally occurring, shallowly sourced, thermogenic gas in northeastern Pennsylvania: AAPG Bulletin, v. 98, p. 373-394.Wilson, E.J., and D. Gerard, eds., 2007, Carbon capture and sequestration: Blackwell Publishing, 296 p.Wilson, N.S.F., 2000, Organic petrology, chemical composition, and reflectance of pyrobitumen from the El Soldado Cu deposit, Chile: International Journal of Coal Geology, v. 43, p. 53-82.Wilson, N.S.F., and M. Zentilli, 2006, Association of pyrobitumen with copper mineralization from the Uchumi and Talcuna districts, central Chile: International Journal of Coal Geology, v. 65, p. 158-169.Wilson, T.H., H. Siriwardane, L. Zhu, R.A. Bajura, R.A. Winschel, J.E. Locke, and J. Bennett, 2012, Fracture model of the Upper Freeport coal: Marshall County West Virginia pilot ECBMR and CO2 sequestration site: International Journal of Coal Geology, v. 104, p. 70-82.Wilson, T.H., H. Siriwardane, L. Zhu, R.A. Bajura, R.A. Winschel, J.E. Locke, and J. Bennett, 2012, Fracture model of the Upper Freeport coal: Marshall County West Virginia pilot ECBMR and CO2 sequestration site: International Journal of Coal Geology, v. 104, p. 70-82.

Winans, R.E., and J.C. Crelling, eds., 1984, Chemistry and characterization of coal macerals: American Chemical Society, ACS Symposium Series 252, 184 p.Winans, R.E., and J.C. Crelling, eds., 1984, Chemistry and characterization of coal macerals: Washington D.C., American Chemical Society, Symposium Series 252, 184 p.Winchester, D.E., 1918, Oil shale of the Uinta Bsain, northeastern Utah: U.S. Geological Survey Bulletin 691-B, p. 27-50.Winchester, D.E., 1918, Results of dry distillation of miscellaneous shale samples: U.S. Geological Survey Bulletin 691-B, p. 51-55.Winchester, D.E., 1923, Oil shale of the Rocky Mountain Region: U.S. Geological Survey Bulletin 729.Winschel, R.A., 1990, The relationship of carbon dioxide emissions with coal rank and sulfur content: Journal of Air & Waste Management Association, v. 40, p. 861-865.Winston, R.B., 1986, Characteristic features and compaction of plant tissues traced from permineralized peat to coal in Pennsylvanian coals (Desmoinesian) from the Illinois basin: International Journal of Coal Geology, v. 6, p. 21-41.

Winston, R.B., 1993, Reassessment of the evidence for primary fusinite and degradofusinite: Organic Geochemistry, v. 20, p. 209-221.Winston, R.B., 1994, Models of the geomorphology, hydrology, and development of domed peat bodies: Geological Society of America Bulletin, v. 106, p. 1594-1604.Wise, D.U., E.S. Belt, and P.C. Lyons, 1991, Clastic diversion by fold salients and blind thrust ridges in coal-swamp development: Geology, v. 19, p. 514-517.Wittenberg, K.W., and S.L. Aldridge, 2007, Colorado decision to shut down coal bed methane production?: RMAG Outcrop, v. 56, no. 10, p. 6-8.Wold, M.B., L.D. Connell, and S.K. Choi, 2008, The role of spatial variability in coal seam parameters on gas outburst behaviour during coal mining: International Journal of Coal Geology, v. 75, p. 1-14.Wolela, A., 2010, Sedimentation, organic maturity, and petroleum potential of the Oligocene-Miocene oil shale deposits, Yayu Basin, southwestern Ethiopia: AAPG Bulletin, v. 94, p. 643-663.Wolf, K.-H.A.A., F. van Bergen, R. Ephraim, and H. Pagnier, 2008, Determination of the cleat angle distribution of the RECOPOL coal seams, using CT-scans and image analysis on drilling cuttings and coal blocks: International Journal of Coal Geology, v. 73, p. 259-272.Wolf, K.-H.A.A., R. Ephraim, W. Bertheux, and J. Bruining, 2001, Coal cleat classification and permeability estimation by image analysis on cores and drilling cuttings: Tuscaloosa, Alabama, Proceedings, International Coalbed Methane Symposium, Paper 102, p. 1-10.Wolf, M., E. Lehndorff, G.L.B. Wiesenberg, M. Stockhausen, L. Schwark, and W. Amelung, 2013, Towards reconstruction of past fire regimes from geochemical analysis of charcoal: Organic Geochemistry, v. 55, p. 11-21.Wong, A.S., and J.D. Robertson, 1993, Multi-elemental analysis of coal and its by-products by simultaneous proton-induced gamma-ray/x-ray emission analysis: Journal of Coal Quality, v. 12, p. 146-150.Wong, A.S., and J.D. Robertson, 1993, Multi-elemental analysis of coal and its by-products by simultaneous proton-induced gamma-ray/x-ray emission analysis: Journal of Coal Quality, v. 12, p. 146-150.Wong, A.S., J.C. Hower, J.D. Robertson, B.O. Haeberlin, G.A. Thomas, and W.H. Schram, 1994, Fluorine partitioning in flue-gas desulfurization: examples from coal-fired power plants in Kentucky: Journal of Coal Quality, v. 13, p. 81-87.

Wilmshurst, J.R., C.F.K. Diessel, R.W.T. Wilkins, C.P. Buckingham, and L. Gammidge, 1995, Coking coal assessment by scanning laser fluorescence microprobe, in J.A. Pajares and J.M.D. Tascon, eds., Coal science: New York, Elsevier, Coal Science and Technology 24, v. 1, p. 323-326.Wilmshurst, J.R., C.F.K. Diessel, R.W.T. Wilkins, C.P. Buckingham, and L. Gammidge, 1995, Coking coal assessment by scanning laser fluorescence microprobe, in J.A. Pajares and J.M.D. Tascon, eds., Coal science: New York, Elsevier, Coal Science and Technology 24, v. 1, p. 323-326.

Winans, R.E., 1984, Chemistry and characterization of coal macerals: overview, in R.E. Winans and J.C. Crelling, eds., Chemistry and Characterization of Coal Macerals: Washington, American Chemical Society, ACS Symposium Series 252, p. 1-20.Winans, R.E., and J.C. Crelling, 1984, Chemistry and characterization of coal macerals: overview, in R.E. Winans and J.C. Crelling, eds., Chemistry and characterization of coal macerals: American Chemical Society, ACS Symposium Series 252, p. 1-20.

Winston, R.B., 1991, Coal quality of the Mary Lee coal group and its relationship to coal resource development, coalbed methane, and geologic history in the Warrior coalfield, Alabama, in D.C. Peters, ed., Geology in coal resource utilization: Fairfax, VA, Techbooks, p. 369-388 (available from AAPG)

Wong, S., D. Macdonald, S. Andrei, W.D. Gunter, X. Deng, D. Law, J. Ye, S. Feng, Z. Fan, and P. Ho, 2010, Conceptual economics of full scale enhanced coalbed methane production and CO2 storage in anthracitic coals at South Qinshui Basin, Shanxi, China: International Journal of Coal Geology, v. 82, p. 280-286.

Wood, G.H., J. Kehn, T.M. Carter, and W.C. Culberston, 1983, Coal resources classification system of the U.S. Geological Survey: U.S. Geological Survey Circular 891, 65 p.Woolard, C.D., J. Strong, and C.R. Erasmus, 2002, Evaluation of the use of modified coal ash as a potential sorbent for organic waste streams: Applied Geochemistry, v. 17, p. 1159-1164.Worden, R.H., 2006, Dawsonite cement in the Triassic Lam Formation, Shabwa Basin, Yemen: A natural analogue for a potential mineral product of subsurface CO2 storage for greenhouse gas reduction: Marine and Petroleum Geology, v. 23, p. 61-77.Worrall, F., and D.G. Pearson, 2001, The development of acidic groundwaters in coal-bearing strata: Part I. Rare earth element fingerprinting: Applied Geochemistry, v. 16, p. 1465-1480.Wray, L.L., and J.E. Schultz, 2001, Coal and coalbed methane in Colorado: Colorado Geological Survey, Special Publication 51, CD-ROM.Wray, L.L., N.V. Koenig, and J.P. Seidle, 2002, Preliminary assessment of coalbed methane potential of the low-rank Denver and Laramie Formation coals, Denver basin, Colorado (abstract): AAPG Annual Convention Official Program, v. 11, p. A193.

Wu, D., H. Deng, B. Zheng, W. Wang, X. Tang, and H. Xiao, 2008, Iodine in Chinese coals and its geochemistry during coalification: Applied Geochemistry, v. 23, p. 2082-2090.Wu, M.M., G.A. Robbins, R.A. Winschel, and F.P. Burke, 1988, Low-temperature coal weathering: its chemical nature and effects on coal properties: Energy and Fuels, v. 2, p. 150-157.Wu, Y., J. Liu, D. Elsworth, H. Siriwardane, and X. Miao, 2011, Evolution of coal permeability: Contribution of heterogeneous swelling processes: International Journal of Coal Geology, v. 88, p. 152-162.Wu, Y., J. Liu, Z. Chen, D. Elsworth, and D. Pone, 2011, A dual poroelastic model for CO2-enhanced coalbed methane recovery: International Journal of Coal Geology, v. 86, p. 177-189.Wüst, R., C.R. Ward, R.M. Bustin, and M.I. Hawke, 2002, Characterization and quantification of inorganic constituents of tropical peats and organic-rich deposits from Tasek Bera (Peninsular Malaysia): implications for coals: International Journal of Coal Geology, v. 49, p. 215-249.Wüst, R., M.I. Hawke, and R.M. Bustin, 2001, Comparing maceral ratios from tropical peatlands with assumptions from coal studies: do classic coal petrographic interpretation methods have to be discarded?: International Journal of Coal Geology, v. 48, p. 115-132.Wüst, R., R.M. Bustin, and J. Ross, 2008, Neo-mineral formation during artificial coalification of low-ash, mineral free-peat material from tropical Malaysia—potential explanation for low ash coals: International Journal of Coal Geology, v. 74, p. 114-122.

Wyszomirski, P., and E. Brylska, 1996, Fly ash in Polish building ceramics — threat or proecology?: Applied Geochemistry, v. 11, p. 351-353.Xianming, X., R.W.T. Wilkins, L. Dehan, L. Zufa, and F. Jiamu, 2000, Investigation of thermal maturity of lower Palaeozoic hydrocarbon source rocks by means of vitrinite-like maceral reflectance — a Tarim basin case study: Organic Geochemistry, v. 31, no. 10, p. 1041-1052.Xiao, D., S. Peng, B. Wang, and X. Yan, 2013, Anthracite bio-degradation by methanogenic consortia in Qinshui Basin: International Journal of Coal Geology, v. 116-117, p. 46-52.Xiao, H.-Y., and C.-Q. Liu, 2011, The elemental and isotopic composition of sulfur and nitrogen in Chinese coals: Organic Geochemistry, v. 42, p. 84-93.Xiao, X., R.W.T. Wilkins, D. Liu, Z. Liu, and J. Shen, 2002, Laser-induced fluorescence microscopy—application to possible high rank and carbonate source rocks: International Journal of Coal Geology, v. 51, p. 129-141.Xiao, X.M., F. Wang, R.W.T. Wilkins, and Z.G. Song, 2007, Origin and gas potential of pyrobitumen in the Upper Proterozoic strata from the Middle Paleo-Uplift of the Sichuan Basin, China: International Journal of Coal Geology, v. 70, p. 264-276.Xiao, X.M., F. Wang, R.W.T. Wilkins, and Z.G. Song, 2007, Origin and gas potential of pyrobitumen in the Upper Proterozoic strata from the Middle Paleo-Uplift of the Sichuan Basin, China: International Journal of Coal Geology, v. 70, p. 264-276.Xiao, X.M., R.W.T. Wilkins, D.H. Liu, Z.F. Liu, and J.M. Fu, 2000, Investigation of thermal maturity of lower Paleozoic hydrocarbon source rocks by means of vitrinite-like maceral reflectance: A Tarim Basin case study: Organic Geochemistry, v. 31, p. 1041-1052.Xiao, X.M., R.W.T. Wilkins, D.H. Liu, Z.F. Liu, and J.M. Fu, 2000, Investigation of thermal maturity of lower Paleozoic hydrocarbon source rocks by means of vitrinite-like maceral reflectance: A Tarim Basin case study: Organic Geochemistry, v. 31, p. 1041-1052.Xiao, X.M., R.W.T. Wilkins, D.H. Liu, Z.F. Liu, and J.M. Fu, 2000, Investigation of thermal maturity of lower Paleozoic hydrocarbon source rocks by means of vitrinite-like maceral reflectance: A Tarim Basin case study: Organic Geochemistry, v. 31, p. 1041-1052.Xiaofeng, W., A. Hoffknecht, X. Jianxin, C. Shanqin, L. Zehong, R. Brocke, and B.D. Erdtmann, 1993, Thermal maturity of the Sinian and early Paleozoic in west Hubei, China, assessed by CAI, reflectance and geochemical studies: Stratigraphy and Paleontology of China, v. 2, p. 19-44.Xiaofeng, W., A. Hoffknecht, X. Jianxin, L. Zehong, C. Shanqin, R. Brocke, and B.D. Erdtmann, 1992, Reflectance of graptolite and its use as indicator of thermal maturity: Bulletin of the Yichang Institute of Geology and Mineral Resources, v. 18, p. 89-92.Xiaofeng, W., B.-D. Erdtmann, A. Hoffknecht, C. Shanqin, C. Xiaohong, L. Zhihong, X. Jianxin, and R. Brocke, 1997, Bioclast reflectance—a new frontier of organic petrology: Beijing, China, Geological Publishing House, 80 p.Xiaofeng, W., B.-D. Erdtmann, A. Hoffknecht, C. Shanqin, C. Xiaohong, L. Zhihong, X. Jianxin, and R. Brocke, 1997, Bioclast reflectance—a new frontier of organic petrology: Beijing, China, Geological Publishing House, 80 p.Xie, J., S. Xue, W. cheng, and G. Wang, 2011Early detection of spontaneous combustion of coal in underground coal mines with development of an ethylene enriching system: International Journal of Coal Geology, v. 85, p. 123-127.Xie, J., S. Xue, W. cheng, and G. Wang, 2011Early detection of spontaneous combustion of coal in underground coal mines with development of an ethylene enriching system: International Journal of Coal Geology, v. 85, p. 123-127.Xie, X., J.K. Volkman, J. Qin, T. Borjigin, L. Bian, and L. Zhen, 2014, Petrology and hydrocarbon potential of microalgal and macroalgal dominated oil shales from the Eocene Huadian Formation, NE China: International Journal of Coal Geology, v. 124, p. 36-47.Xie, X., J.K. Volkman, J. Qin, T. Borjigin, L. Bian, and L. Zhen, 2014, Petrology and hydrocarbon potential of microalgal and macroalgal dominated oil shales from the Eocene Huadian Formation, NE China: International Journal of Coal Geology, v. 124, p. 36-47.Xu, B., X. Li, M. Haghighi, W. Ren, X. Du, D. Chen, and Y. Zhai, 2013, Optimization of hydraulically fractured well configuration in anisotropic coal-bed methane reservoirs: Fuel, v. 107, p. 859-865. (well spacing)Xu, B., X. Li, M. Haghight, X. Du, X. Yang, D. Chen, and Y. Zhai, 2013, An analytical model for desorption area in coal-bed methane production wells: Fuel, v. 106, p. 766-772. (well spacing)Xu, H., D. Tang, J. Zhang, W. Yin, W. Zhang, and W. Lin, 2011, Factors affecting the development of the pressure differential in Upper Paleozoic gas reservoirs in the Sulige and Yulin areas of the Ordos Basin, China: International Journal of Coal Geology, v. 85, p. 103-111.Xu, H., D.Z. Tang, D.M. Liu, S.H. Tang, F. Yang, X.Z. Chen, W. He, and C.M. Deng, 2012, Study on coalbed methane accumulation characteristics and favorable areas in the Binchang area, southwestern Ordos Basin, China: International Journal of Coal Geology, v. 95, p. 1-11.Xu, H., D.Z. Tang, S.H. Tang, J.L. Zhao, Y.J. Meng, and S. Tao, 2014, A dynamic prediction model for gas-water effective permeability based on coalbed methane production data: International Journal of Coal Geology, v. 121, p. 44-52.

Wong, S., K. MacLeod, M. Wold, W.D. Gunter, M.J. Mavor, and J. Gale, 2001, CO2-enhanced coalbed methane recovery demonstration pilot — a case for Australia: Tuscaloosa, Alabama, Proceedings, International Coalbed Methane Symposium, Paper 148, p. 75-86.Wood, G.D., A.M. gabriel, and J.C. Lawson, 1996, Palynological techniques — processing and microscopy, in J. Jansonius and D.C. McGregor, eds., Palynology: principles and applications: American Association of Stratigraphic Palynologists, v. 1, p. 29-50.

Wright, C.R., 1975, Environments within a typical Pennsylvanian cyclothem, in E.D. McKee, E.J. Crosby, and others, Paleotectonic investigations of the Pennsylvanian System in the United States; Part II. Interpretive summary and special features of the Pennsylvanian System: U.S. Geological Survey Professional Paper 853, p. 73-84.

Wyman, R.E., 1984, Gas resources in Elmworth coal seams, in J.A. Masters, ed., Elmworth - a case study of a deep basin gas field: Canadian Society of Petroleum Geologists Memoir 38, p. 173-187.

Xu, T., G. Yue, F. Wang, and N. Liu, 2014, Using natural CO2 reservoir to constrain geochemical models for CO2 geological sequestration: Applied Geochemistry, v. 43, p. 22-34.Xu, T., J.A. Apps, and K. Pruess, 2004, Numerical simulation of CO2 disposal by mineral trapping in deep aquifers: Applied Geochemistry, v. 19, p. 917-936.Xu, T., J.A. Apps, and K. Pruess, 2005, Mineral sequestration of carbon dioxide in a sandstone-shale system: Chemical Geology, v. 217, p. 295-318.Xu, X., Q. Chen, and H. Fan, 2003, The influence of high-temperature crystallite growth and petrography of pulverized char on combustion characteristics: Fuel, v. 82, p. 853-858.Xue, S., J. Wang, J. Xie, and J. Wu, 2010, A laboratory study on the temperature dependence of the radon concentration in coal: International Journal of Coal Geology, v. 83, p. 82-84.Xue, S., Y. Wang, J. Xie, and G. Wang, 2011, A coupled approach to simulate initiation of outbursts of coal and gas—Model development: International Journal of Coal Geology, v. 86, p. 222-230.

Yalçin, M.N., H.J. Schenk, and R.G. Schaefer, 1994, Modelling of gas generation in coals of the Zonguldak basin (northwestern Turkey): International Journal of Coal Geology, v. 25, p. 195-212.Yalçin, M.N., S. Inan, G. Gürdal, U. Mann, and R.G. Schaefer, 2002, Carboniferous coals of the Zonguldak basin (northwest Turkey): Implications for coalbed methane potential: AAPG Bulletin, v. 86, p. 1305-1328.Yalçin, M.N., S. Inan, G. Gürdal, U. Mann, and R.G. Schaefer, 2002, Carboniferous coals of the Zonguldak basin (northwest Turkey): Implications for coalbed methane potential: AAPG Bulletin, v. 86, p. 1305-1328.Yalçin, M.N., S. Inan, H. Hoşgörmez, and S. Çetin, 2003, A new Carboniferous coal/shale driven gas play in the western Black Sea region (Turkey): Marine and Petroleum Geology, v. 19, p. 1241-1256.Yamaji, A., and M. Takahashi, 1988, Estimation of relative depth of burial using vitrinite reflectance: implications for a sedimentary basin formation by basement tilting: International Journal of Coal Geology, v. 10, p. 41-50.Yamazaki, T., K. Aso, and J. Chinju, 2006, Japanese potential of CO2 sequestration in coal seams: Applied Energy, v. 83, p. 911-920.Yan, J., Z. Bai, W. Li, and J. Bai, 2014, Direct liquefaction of a Chinese brown coal and CO2 gasification of the residues: Fuel, v. 136, p. 280-286.Yan, Z., G. Liu, R. Sun, D. Wu, B. Wu, and C. Zhou, 2013, Mercury distribution in coals influenced by magmatic intrusions, and surface waters from the Huaibei Coal Mining District, Anhui, China: Applied Geochemistry, v. 33, p. 298-305.Yang, C., and R. Hesse, 1993, Diagenesis and anchimetamorphism in an overthrust belt, external domain of the Taconian Orogen, southern Canadian Appalachians -- II. Paleogeothermal gradients derived from maturation of different types of organic matter: Organic Geochemistry, v. 20, p. 381-403.Yang, C., and R. Hesse, 1993, Diagenesis and anchimetamorphism in an overthrust belt, external domain of the Taconian Orogen, southern Canadian Appalachians -- II. Paleogeothermal gradients derived from maturation of different types of organic matter: Organic Geochemistry, v. 20, p. 381-403.Yang, F., Z. Pang, L. Lin, Z. Jia, F. Zhang, Z. Duan, and Z. Zong, 2013, Hydrogeochemical and isotopic evidence for trans-formational flow in a sedimentary basin: Implications of CO2 storage: Applied Geochemistry, v. 30, p. 4-15.Yang, M., G. Liu, R. Sun, C.-L. Chou, and L. Zheng, 2012, Characterization of intrusive rocks and REE geochemistry of coals form the Zhuji coal mine, Huainana Coalfield, Anhui, China: International Journal of Coal Geology, v. 94, p. 283-295.Yang, R.T., and J.T. Saunders, 1985, Adsorption of gases on coals and heat-treated coals at elevated temperature and pressure: 1. Adsorption from hydrogen and methane as single gases: Fuel, v. 64, p. 616-620.Yang, T.H., T. Xu, H.Y. Liu, C.A. Tang, B.M. Shi, and Q.X. Yu, 2011, Stress-damage-flow coupling model and its application to pressure relief coal bed methane in deep coal seam: International Journal of Coal Geology, v. 86, p. 357-366.Yang, T.H., T. Xu, H.Y. Liu, C.A. Tang, B.M. Shi, and Q.X. Yu, 2011, Stress-damage-flow coupling model and its application to pressure relief coal bed methane in deep coal seam: International Journal of Coal Geology, v. 86, p. 357-366.Yang, W., B.-Q. Lin, Y.-A. Qu, S. Zhao, C. Zhai, L.-L. Jia, and W.-Q. Zhao, 2011, Mechanism of strata deformation under protective seam and its application for relieved methane control: International Journal of Coal Geology, v. 85, p. 300-306.Yang, Y., R. Zou, Z. Shi, and R. Jiang, eds., 1996, Atlas for coal petrography of China: Beijing, China University of Mining and Technology Press, ISBN 7-81040-519-5, 323 p.Yao, S., J. Cao, K. Zhang, K. Jiao, H. Ding, and W. Hu, 2012, Artificial bacterial degradation and hydrous pyrolysis of suberin: Implications for hydrocarbon generation of suberinite: Organic Geochemistry, v. 47, p. 22-33.Yao, S., J. Cao, K. Zhang, K. Jiao, H. Ding, and W. Hu, 2012, Artificial bacterial degradation and hydrous pyrolysis of suberin: Implications for hydrocarbon generation of suberinite: Organic Geochemistry, v. 47, p. 22-33.Yao, Y., and D. Liu, 2012, Effects of igneous intrusions on coal petrology, pore-fracture and coalbed methane characteristics in Hongyang, Handan and Huaibei coalfields, north China: International Journal of Coal Geology, v. 96-97, p. 72-81.Yao, Y., D. Liu, and T. Yan, 2014, Geological and hydrogeological controls on the accumulation of coalbed methane in the Weibei field, southeastern Ordos Basin: International Journal of Coal Geology, v. 121, p. 148-159.Yao, Y., D. Liu, and Y. Qiu, 2013, Variable gas content, saturation, and accumulation characteristics of Weibei coalbed methane pilot-prodution field in the southeastern Ordos Basin, China: AAPG Bulletin, v. 97, p. 1371-1393.Yao, Y., D. Liu, D. Tang, S. Tang, and W. Huang, 2008, Fractal characterization of adsorption-pores of coals from north China: An investigation on CH4 adsorption capacity of coals: International Journal of Coal Geology, v. 73, p. 27-42.Yao, Y., D. Liu, D. Tang, S. Tang, Y. Che, and W. Huang, 2009, Preliminary evaluation of the coalbed methane production potential and its geological controls in the Weibei coalfield, southeastern Ordos Basin, China: International Journal of Coal Geology, v. 78, p. 1-15.Yao, Y., D. Liu, Y. Che, D. Tang, S. Tang, and W. Huang, 2010, Petrophysical characterization of coals by low-field nuclear magnetic resonance (NMR): Fuel, v. 89, p. 1371-1380.Yao, Z.T., M.S. Xia, P.K. Sarker, and T. Chen, 2014, A review of the alumina recovery from coal fly ash, with a focus in China: Fuel, v. 120, p. 74-85.Yardim, M.F., M. Tolay, E. Ekinci, and K.D. Bartle, 1986, Liquid products from Turkish asphaltite — solvent extraction followed by pyrolysis: Erdol und Kohle-Erdgas-Petrochemie, v. 39, p. 471-472.Yarzab, R.F., P.H. Given, W. Spackman, and A. Davis, 1980, Dependence of coal liquefaction behavior on coal characteristics. 4. Cluster analyses for characteristics of 104 coals: Fuel, v. 59, p. 81-92.Ye, Z., D. Chen, and J.G. Wang, 2014, Evaluation of the non-Darcy effect in coalbed methane production: Fuel, v. 121, p. 1-10.

Yefimov, V., 1993, Development of oil shale processing industry in Estonia before World War II: Oil Shale, v. 10, p. 237-246.Yefimov, V., I. Rooks, and H. Rootalu, 1994, Development of the oil shale processing industry in Estonia after World War II: Oil Shale, v. 11, p. 265-276.Yeloff, D., and C. Hunt, 2005, Fluorescence microscopy of pollen and spores: a tool for investigating environmental change: Review of Palaeobotany and Palynology, v. 133, p. 203-219.

Yalçin, M.N., and S. Inan, 2001, Timing of oil generation and expulsion from the Carboniferous humic coals of the Zonguldak basin, in A.S. Derman, F. Toksoy, and E. Yilmaz, eds., Proceedings of the 2nd International Symposium on the Petroleum Geology and Hydrocarbon Potential of the Black Sea Area: Turkish Association of Petroleum Geologists Bulletin, v. 4, p. 133-147.

Yee, D., J.P. Seidle, and W.B. Hanson, 1993, Gas sorption on coal and measurement of gas content, in B.E. Law and D.D. Rice, eds., Hydrocarbons from coal: AAPG Studies in Geology 38, p. 203-218.

Yen, T.F., and G.V. Chilingarian, 1976, Introduction to oil shales, in T.F. Yen and G.V. Chilingarian, eds., Oil shale: New York, Elsevier Scientific Publishing Company, Developments in Petroleum Science, v. 5, p. 1-12.

Yen, T.F., and G.V. Chilingarian, eds., 1976, Oil shale: New York, Elsevier Scientific Publishing Company, Developments in Petroleum Science, v. 5, 292 p.Yerramilli, S.S., and R. Yerrmailli, 2008, Water management in CBM reservoirs: Hart’s E&P, v. 81, no. 6, p. 80-81.Yi, J., I.Y. Akkutlu, and C.V. Deutsch, 2008, Gas transport in bidisperse coal particles: Investigation for an effective diffusion coefficient in coalbeds: Journal of Canadian Petroleum Technology, v. 47, no. 10, p. 1-7.Yi, J., I.Y. Akkutlu, C.Ő. Karacan, and C.R. Clarkson, 2009, Gas sorption and transport in coals: A poroelastic medium approach: International Journal of Coal Geology, v. 77, p. 137-144.Yi, J., I.Y. Akkutlu, C.Ő. Karacan, and C.R. Clarkson, 2009, Gas sorption and transport in coals: A poroelastic medium approach: International Journal of Coal Geology, v. 77, p. 137-144.Yossifova, M., S. Valćeva, and E. Djourova, 2007, Mineralogy and environmental geochemistry of lagooned ashes resulted from combustion of Maritza East lignite, Bulgaria: International Journal of Coal Geology, v. 71, p. 287-302.Yossifova, M.G., 2007, Mineral and inorganic chemical composition of the Pernik coal, Bulgaria: International Journal of Coal Geology, v. 72, p. 268-292.Yossifova, M.G., 2007, Mineral and inorganic chemical composition of the Pernik coal, Bulgaria: International Journal of Coal Geology, v. 72, p. 268-292.Yossifova, M.G., 2014, Petrography, mineralogy and geochemistry of Balkan coals and their waste products: International Journal of Coal Geology, v. 122, p. 1-20.Yossifova, M.G., G.M. Eskenazy, and S.P. Valčeva, 2011, Petrology, mineralogy, and geochemistry of submarine coals and petrified forest in the Sozopol Bay, Bulgaria: International Journal of Coal Geology, v. 87, p. 212-225.Yossifova, M.G., G.M. Eskenazy, and S.P. Valčeva, 2011, Petrology, mineralogy, and geochemistry of submarine coals and petrified forest in the Sozopol Bay, Bulgaria: International Journal of Coal Geology, v. 87, p. 212-225.Youjin, D., L. Dongkun, and X. Liangyu, 2010, Cash flow analysis assesses China;s CBM resource viability: Oil & Gas Journal, v. 108.24, p. 45-49.Young, D.P., and T.J. Pratt, 2005, Coal gas reservoir assessment—WIC Region: GasTIPS, v. 11, no. 1, p. 9-13.

Yu, H., G. Zhou, W. Fan, and J. Ye, 2007, Predicted CO2 enhanced coalbed methane recovery and CO2 sequestration in China: International Journal of Coal Geology, v. 71, p. 345-357.Yu, H., G. Zhou, W. Fan, and J. Ye, 2007, Predicted CO2 enhanced coalbed methane recovery and CO2 sequestration in China: International Journal of Coal Geology, v. 71, p. 345-357.Yu, H., J. Yuan, W. Guo, J. Cheng, and Q. Hu, 2008, A preliminary laboratory experiment on coalbed methane displacement with carbon dioxide injection: International Journal of Coal Geology, v. 73, p. 156-166.Yu, H., J. Yuan, W. Guo, J. Cheng, and Q. Hu, 2008, A preliminary laboratory experiment on coalbed methane displacement with carbon dioxide injection: International Journal of Coal Geology, v. 73, p. 156-166.Yu, H., L. Zhou, W. Guo, J. Cheng, and Q. Hu, 2008, Predictions of the adsorption equilibrium of methane/carbon dioxide binary gas on coals using Langmuir and ideal adsorbed solution theory under feed gas conditions: International Journal of Coal Geology, v. 73, p. 115-129.Yu, H., L. Zhou, W. Guo, J. Cheng, and Q. Hu, 2008, Predictions of the adsorption equilibrium of methane/carbon dioxide binary gas on coals using Langmuir and ideal adsorbed solution theory under feed gas conditions: International Journal of Coal Geology, v. 73, p. 115-129.Yu, H., W. Guo, J. Cheng, and Q. Hu, 2008, Impact of experimental parameters for manometric equipment on CO2 isotherms measured: Comment on "Inter-laboratory comparison II: CO2 isotherms measured on moisture-equilibrated Argonne premium coals at 55°C and up to 15 MPa" by Goodman et al. (2007): International Journal of Coal Geology, v. 74, p. 250-258. Yu, K., J.C. Barry, and J.S. Esterle, 1997, Analysis of coal banding texture and implications for megascopic image analysis: International Journal of Coal Geology, v. 33, p. 1-18.Yuan, L., and A.C. Smith, 2011, CO and CO2 emissions from spontaneous heating of coal under different ventilation rates: International Journal of Coal Geology, v. 88, p. 24-30.Yudovich, Y.E., 2003, Coal inclusions in sedimentary rocks: a geochemical phenomenon. A review: International Journal of Coal Geology, v. 56, p. 203-222.Yudovich, Y.E., 2003, Notes on the marginal enrichment of Germanium in coal beds: International Journal of Coal Geology, v. 56, p. 223-232.Yudovich, Y.E., and M.P. Ketris, 2005, Arsenic in coal: a review: International Journal of Coal Geology, v. 61, p. 141-196.Yudovich, Y.E., and M.P. Ketris, 2005, Mercury in coal: a review, part 1. Geochemistry: International Journal of Coal Geology, v. 62, p. 107-134.Yudovich, Y.E., and M.P. Ketris, 2005, Mercury in coal: a review, part 2. Coal use and environmental problems: International Journal of Coal Geology, v. 62, p. 135-165.Yudovich, Y.E., and M.P. Ketris, 2006, Chlorine in coal: a review: International Journal of Coal Geology, v. 67, p. 127-144.Yudovich, Y.E., and M.P. Ketris, 2006, Selenium in coal: a review: International Journal of Coal Geology, v. 67, p. 112-126.Yue, M., and F. Zhao, 2008, Leaching experiments to study the release of trace elements from mineral separates from Chinese coals: International Journal of Coal Geology, v. 73, p. 43-51.Yue, M., and F. Zhao, 2008, Leaching experiments to study the release of trace elements from mineral separates from Chinese coals: International Journal of Coal Geology, v. 73, p. 43-51.Yule, B.L., S. Roberts, and J.E.A. Marshall, 2000, The thermal evolution of sporopollenin: Organic Geochemistry, v. 31, p. 859-870.

Yürüm, Y., ed., 1988, New trends in coal science: Boston, Kluwer Academic Publishers, 529 p.Yushkin, N.P., 1990, Fibrous forms of natural solid hydrocarbons: International Geology Review, v. 32, p. 1041-1050.Yzdi, M., and S.A. Esmaeilnia, 2003, Dual-energy gamma-ray technique for quantitative measurement of coal ash in the Shahroud mine, Iran: International Journal of Coal Geology, v. 55, p. 151-156.Zabetakis, M.G., M. Deul, and M.L. Skow, 1973, Methane control in United States coal mines - 1972: U.S. Bureau of Mines Information Circular 8600, 22 p.Zabetakis, M.G., T.D. Moore, Jr., A.E. Nagel, and J.E. Carpetta, 1972, Methane emission in coal mines: effects of oil and gas wells: U.S. Bureau of Mines Report of Investigations 7658, 9 p.

Young, G.B.C., 1998, Computer modeling and simulation of coalbed methane resources, in R.M. Flores, ed., Coalbed methane: from coal-mine outbursts to a gas resource: International Journal of Coal Geology, v. 35, p. 369-379.Younger, P.L., D.J. Roddy, and G. González, 2010, King coal: restoring the monarchy by underground gasification coupled to CCS, in B.A. Vining and S.C. Pickering, eds., Petroleum geology: from mature basins to new frontiers: London, Geological Society, Proceedings of the 7 th Petroleum Geology Conference, p. 1155-1163.Younger, P.L., D.J. Roddy, and G. González, 2010, King coal: restoring the monarchy by underground gasification coupled to CCS, in B.A. Vining and S.C. Pickering, eds., Petroleum geology: from mature basins to new frontiers: London, Geological Society, Proceedings of the 7 th Petroleum Geology Conference, p. 1155-1163.

Yurum, Y., and E. Ekinci, 1995, Asphaltites: composition and conversion, in C. Snape, ed., Composition, geochemistry and conversion of oil shales: Boston, Kluwer Academic Publishers, NATO ASI Series C, Mathematical and Physical Sciences, v. 455, p. 329-345.

Zaccone, C., G. Rein, V. D’Orazio, R.M. Hadden, C.M. Belcher, and T.M. Miano, 2014, Smouldering fire signatures in peat and their implications for palaeoenvironmental reconstructions: Geochimica et Cosmochimica Acta, v. 137, p. 134-146.Zaitseva, L., A. Ivanova, and H. Zhernova, 2004, Studies of the coal facies in eastern Ukraine: International Journal of Coal Geology, v. 58, p. 75-85.Zarębska, K., and G. Ceglarska-Stefańska, 2008, The change in effective stress associated with swelling during carbon dioxide sequestration on natural gas recovery: International Journal of Coal Geology, v. 74, p. 167-174.Zarębska, K., and G. Ceglarska-Stefańska, 2008, The change in effective stress associated with swelling during carbon dioxide sequestration on natural gas recovery: International Journal of Coal Geology, v. 74, p. 167-174.Zarrouk, S.J., and T.A. Moore, 2009, Preliminary reservoir model of enhanced coalbed methane (ECBM) in a subbituminous coal seam, Huntly coalfield, New Zealand: International Journal of Coal Geology, v. 77, p. 153-161.Zawadzki, J., P. Fabijańczyk, and H. Badura, 2013, Estimation of methane content in coal mines using supplementary physical measurements and multivariable geostatistics: International Journal of Coal Geology, v. 118, p. 33-44.Zdravkov, A., A. Bechtel, R.F. Sachsenhofer, J. Kortenski, and R. Gratzer, 2011, Vegetation differences and diagenetic changes between two Bulgarian lignite deposits – Insights from coal petrology and biomarker composition: Organic Geochemistry, v. 42, p. 237-254.Zdravkov, A., I. Kostova, and J. Kortenski, 2007, Properties and depositional environment of the Neogene Elhovo lignite, Bularia: International Journal of Coal Geology, v. 71, p. 488-504.Zdravkov, A., I. Kostova, R.F. Sachsenhofer, and J. Kortenski, 2006, Reconstruction of paleoenvironment during coal deposition in the Neogene Karlovo graben, Bulgaria: International Journal of Coal Geology, v. 67, p. 79-94.

Zeiss, Reflection microscope photometry: application -- measurements on coal samples: Zeiss manual, A 41-825.8-e.Zeng, R., X. Zhuang, N. Koukouzas, and W. Xu, 2005, Characterization of trace elements in sulphur-rich Late Permian coals in the Heshan coal field, Guangxi, south China: International Journal of Coal Geology, v. 61, p. 87-95.Zhang, E., A. Davis, T.P. Filley, and P.G. Hatcher, 1993, Possible influence of organic sulfur incorporation on optical features and chemical structures of perhydrous vitrinite in coals of western Pennsylvania (abstract): American Chemical Society, Division of Geochemistry, 206th ACS National Meeting, abstract 96.Zhang, E., and A. Davis, 1993, Coalification patterns of the Pennsylvanian coal measures in the Appalachian foreland basin, western and south-central Pennsylvania: GSA Bulletin, v. 105, p. 162-174.Zhang, E., G.D. Mitchell, A. Davis, and P.G. Hatcher, 1994, The effect of organic sulfur incorporation on reflectance and fluorescence properties of vitrinite in western Pennsylvania coals (abstract): American Chemical Society, 208th ACS National Meeting, Division of Geochemistry, abstract 27.Zhang, E., R.J. Hill, B.J. Katz, and Y. Tang, 2008, Modeling of gas generation from the Cameo coal zone in the Piceance Basin, Colorado: AAPG Bulletin, v. 92, p. 1077-1106.Zhang, H., K. Chen, J. Yan, and M. Ni, 2002, The fragmentation of coal particles during the coal combustion in a fluidized bed: Fuel, v. 81, p. 1835-1840.Zhang, J., 2014, Numerical simulation of hydraulic fracturing coalbed methane reservoir: Fuel, v. 136, p. 57-61.Zhang, J., D. Ren, C. Zheng, R. Zeng, C.-L. Chou, and J. Liu, 2002, Trace element abundances in major minerals of Late Permian coals from southwestern Guizhou Province, China: International Journal of Coal Geology, v. 53, p. 55-64.Zhang, J., D. Ren, Y. Zhu, C.-L. Chou, R. Zeng, and B. Zheng, 2004, Mineral matter and potentially hazardous trace elements in coals from Qianxi fault depression area in southwestern Guizhou, China: International Journal of Coal Geology, v. 57, p. 49-61.Zhang, J., Y. Zhao, C. Wei, B. Yao, and C. Zheng, 2010, Mineralogy and microstructure of ash deposits from the Zhuzhou coal-fired power plant in China: International Journal of Coal Geology, v. 81, p. 309-319.Zhang, S., 2008, New insights into Ordovician oil shales in Hudson Bay Basin: their number, stratigraphic position, and petroleum potential: Bulletin of Canadian Petroleum Geology, v. 56, p. 300-324.Zhang, S., B. Zhang, G. Zhu, H. Wang, and Z. Li, 2011, Geochemical evidence for coal-derived hydrocarbons and their charge history in the Dabei Gas Field, Kuqa Thrust Belt, Tarim Basin, NW China: Marine and Petroleum Geology, v. 28, p. 1364-1375.Zhang, W., T. Xu, and Y. Li, 2011, Modeling of fate and transport of coinjection of H2S with CO2 in deep saline formations: Journal of Geophysical Research, v. 116, B02202, 13 p.

Zhang, Y., J. Wu, L. Chang, J. Wang, S. Xue, and Z. Li, 2013, Kinetic and thermodynamic studies on the mechanism of low-temperature oxidation of coal: A case study of Shendong coal (China): International Journal of Coal Geology, v. 120, p. 41-49.Zhao, F., Z. Cong, H. Sun, and D. Ren, 2007, The geochemistry of rare earth elements (REE) in acid mine drainage from the Sitai coal mine, Shanxi Province, north China: International Journal of Coal Geology, v. 70, p. 184-192.Zhao, L., C.R. Ward, D. French, and I.T. Graham, 2012, Mineralogy of the volcanic-influenced Great Northern coal seam in the Sydney Basin, Australia: International Journal of Coal Geology, v. 94, p. 94-110.Zhao, L., C.R. Ward, D. French, I.T. Graham, 2013, Mineralogical composition of Late Permian coal seams in the Songzao coalfield, southwestern China: International Journal of Coal Geology, v. 116-117, p. 208-226.

Zhao, Y., J. Zhang, and C. Zheng, 2012, Transformation of aluminum-rich minerals during combustion of a bauxite-bearing Chinese coal: International Journal of Coal Geology, v. 94, p. 182-190.Zhao, Y., J. Zhang, and C. Zheng, 2012, Transformation of aluminum-rich minerals during combustion of a bauxite-bearing Chinese coal: International Journal of Coal Geology, v. 94, p. 182-190.Zhao, Y., J. Zhang, C.-L. Chou, Y. Li, Z. Wang, Y. Ge, and C. Zheng, 2008, Trace element emissions from spontaneous combustion of gob piles in coal mines, Shanxi, China: International Journal of Coal Geology, v. 73, p. 52-62.Zhao, Y., J. Zhang, C.-L. Chou, Y. Li, Z. Wang, Y. Ge, and C. Zheng, 2008, Trace element emissions from spontaneous combustion of gob piles in coal mines, Shanxi, China: International Journal of Coal Geology, v. 73, p. 52-62.

Zheng, L., G. Liu, and C.-L. Chou, 2008, Abundance and modes of occurrence of mercury in some low-sulfur coals from China: International Journal of Coal Geology, v. 73, p. 19-26.Zheng, L., G. Liu, C. Qi, Y. Zhang, and M. Wong, 2008, The use of sequential extraction to determine the distribution and modes of occurrence of mercury in Permian Huaibei coal, Anhui Province, China: International Journal of Coal Geology, v. 73, p. 139-155.Zheng, L., G. Liu, L. Wang, and C.-L. Chou, 2008, Composition and quality of coals in the Huaibei coalfield, Anhui, China: Journal of Geochemical Exploration, v. 97, p. 59-68.Zhiming, W., and Z. Jian, 2009, CBM reservoir thickness affects production from horizontal wells: Oil & Gas Journal, v. 107.16, p. 42-46.Zhou, F., F. Hussain, and Y. Cinar, 2013, Injecting pure N2 and CO2 to coal for enhanced coalbed methane: Experimental observations and numerical simulation: International Journal of Coal Geology, v. 116-117, p. 53-62.Zhou, F., W. Ren, D. Wang, T. Song, X. Li, and Y. Zhang, 2006, Application of three-phase foam to fight an extraordinarily serious coal mine fire: International Journal of Coal Geology, v. 67, p. 95-100.

Zeidler, W., 1973, Coal and coke preparation for microscopic examination, in P. Gray, ed., The encyclopedia of microscopy and microtechnique: New York, Van Nostrand Reinhold Co., p. 86-95.

Zhang, X., C. Chen, X. Sun, and Y. Zheng, 1995, Maceral and rank influences on the morphology and reactivity of coal char, in J.A. Pajares and J.M.D. Tascon, eds., Coal science: New York, Elsevier, Coal Science and Technology 24, v. 1, p. 307-310.

Zhao, P.Q., Z.Q. Mao, D. Jin, B.D. Sun, X. Pang, and Q.W. Fan, 2014, An improved petrophysical volume model for proximate analysis in coalbed methane reservoir: Unconventional Resources Technology Conference proceedings, URTeC 1920522, 10 p. http://archives.datapages.com/data/urtec/2014/1920522.pdf

Zhaojun, L., 2009, Oil shale in China: Beijing, China Scientific Book Service Co., 343 p. (Chinese with English summary) http://www.hceis.com/book.asp?id=8304

Zhou, J., X. Zhuang, A. Alastuey, X. Querol, and J. Li, 2010, Geochemistry and mineralogy of coal in the recently explored Zhundong large coal field in the Junggar Basin, Xinjiang Province, China: International Journal of Coal Geology, v. 82, p. 51-67.Zhou, Q., X. Xiao, L. Pan, and H. Tian, 2014, The relationship between micro-Raman spectral parameters and reflectance of solid bitumen: International Journal of Coal Geology, v. 121, p. 19-25.Zhou, Q., X.M. Xiao, H. Tian, and R.W.T. Wilkins, 2013, Oil charge history of bitumens of differing maturities in exhumed Palaeozoic reservoir rocks at Tianjingshan, NW Sichuan Basin, southern China: Journal of Petroleum Geology, v. 36, p. 363-382.Zhou, Y., Y. Ren, D. Tang, and B. Bohor, 1994, Characteristics of zircons from volcanic ash-derived tonsteins in Late Permian coal fields of eastern Yunnan, China: International Journal of Coal Geology, v. 25, p. 243-264.Zhou, Z., C.J. Ballentine, R. Kipfer, M. Schoell, and S. Thibodeaux, 2005, Noble gas tracing of groundwater/coalbed methane interaction in the San Juan Basin, USA: Geochimica et Cosmochimica Acta, v. 69, p. 5413-5428.Zhou, Z., C.J. Ballentine, R. Kipfer, M. Schoell, and S. Thibodeaux, 2005, Noble gas tracing of groundwater/coalbed methane interaction in the San Juan Basin, USA: Geochimica et Cosmochimica Acta, v. 69, p. 5413-5428.Zhu, W.C., C.H. Wei, J. Liu, H.Y. Qu, and D. Elsworth, 2011, A model of coal-gas interaction under variable temperatures: International Journal of Coal Geology, v. 86, p. 213-221.Zhu, Y., Y. Li, J. Zhou, and S. Gu, 2012, Geochemical characteristics of Tertiary coal-bearing source rocks in Xihu depression, East China Sea Basin: Marine and Petroleum Geology, v. 35, p. 154-165.

Zhuang, X., S. Su, M. Xiao, J. Li, A. Alstuey, and X. Querol, 2012, Mineralogy and geochemistry of the Late Permian coals in the Huayingshan coal-bearing area, Sichuan Province, China: International Journal of Coal Geology, v. 94, p. 271-282.Zhuang, X., S. Su, M. Xiao, J. Li, A. Alstuey, and X. Querol, 2012, Mineralogy and geochemistry of the Late Permian coals in the Huayingshan coal-bearing area, Sichuan Province, China: International Journal of Coal Geology, v. 94, p. 271-282.Zhuang, X., X. Querol, A. Alastuey, F. Plana, N. Moreno, J.M. Andrés, and J. Wang, 2007, Mineralogy and geochemistry of the coals from the Chongqing and southeast Hubei coal mining districts, south China: International Journal of Coal Geology, v. 71, p. 263-275.Zhuang, X., X. Querol, A. Alastuey, R. Juan, F. Plana, A. Lopez-Soler, G. Du, and V.V. Martynov, 2006, Geochemistry and mineralogy of the Cretaceous Wulantuga high-germanium coal deposit in Shengli coal field, Inner Mongolia, northeastern China: International Journal of Coal Geology, v. 66, p. 119-136.

Zielinski, R.A., and R.B. Finkelman, 1997, Radioactive elements in coal and fly ash: abundance, forms, and environmental significance: U.S. Geological Survey, Fact Sheet FS-163-97, 4 p.Ziemba, L., 2009, Smarter technology reduces drill time: An investor’s guide to unconventional gas, A supplement to Oil and Gas Investor, p. 20-24.Zimmerman, R.E., 1979, Evaluating and testing the coking properties of coal: San Francisco, Miller Freeman Publications, 144 p.Zippi, P.A., 1991, SEM and light microscope mounting and specimen location technique for same-specimen study of palynological strew mounts: Micropaleontology, v. 37, p. 407-413.

Zodrow, E.L., 2009, Pennsylvanian seed-fern trunk: fusinite, charcoal, or both?: TSOP Newsletter, v. 26, no. 3, p. 7.Zodrow, E.L., M. Mastalerz, U. Werner-Zwanziger, and J.A. D’Angelo, 2010, Medullosalean fusain trunk from the roof rocks of a coal seam: insight from FTIR and NMR (Pennsylvanian Sydney coalfield, Canada): International Journal of Coal Geology, v. 82, p. 116-124.

Zodrow, E.L., P.C. Lyons, and M.A. Millay, 1996, Geochemistry of autochthonous and hypautochthonous siderite-dolomite coal-balls (Foord Seam, Bolsovian, Upper Carboniferous), Nova Scotia, Canada: International Journal of Coal Geology, v. 29, p. 199-216.Zou, Y.-R., and P. Peng, 2001, Overpressure retardation of organic-matter maturation: a kinetic model and its application: Marine and Petroleum Geology, v. 18, p. 707-713.Zou, Y.-R., and P. Peng, 2001, Overpressure retardation of organic-matter maturation: a kinetic model and its application: Marine and Petroleum Geology, v. 18, p. 707-713.Zou, Y.-R., C. Zhao, Y. Wang, W. Zhao, P. Peng, and Y. Shuai, 2006, Characteristics and origin of natural gases in the Kuqa Depression of Tarim Basin, NW China: Organic Geochemistry, v. 37, p. 280-290.

Zuber, M.D., and C. Hopkins, 1996, Coalbed methane engineering methods: SPE Short Course Manual, S.A. Holditch & Associates, Inc.Zuber, M.D., and C.M. Boyer, II, 2001, Analysis optimizes CBM economics: American Oil & Gas Reporter, v. 44, no. 12, p. 62, 65-67.Zuber, M.D., and C.M. Boyer, II, 2001, Comparative analysis of coalbed methane production trends and variability — impact on exploration and production: Tuscaloosa, Alabama, Proceedings, International Coalbed Methane Symposium, Paper 136, p. 245-256.Zuber, M.D., and C.M. Boyer, II, 2002, Coalbed-methane evaluation techniques — the current state of the art: Journal of Petroleum Technology, v. 54, no. 2, p. 66-68.

Zyryanov, V.V., S.A. Petrov, and A.A. Matvienko, 2011, Characterization of spinel and magnetospheres of coal fly ashes collected in power plants in the former USSR: Fuel, v. 90, p. 486-492.

Zhu, Z. (ed.), M. Bouchard, D. Butman, T. Hawbaker, Z. Li, J. Liu, S. Liu, C. McDonald, R. Reker, K. Sayler, B. Sleeter, T. Sohl, S. Stackpoole, A. Wein, and Z. Zhu, 2011, Baseline and projected future carbon storage and greenhouse-gas fluxes in the Great Plains region of the United States: U.S. Geological Survey Professional Paper 1787, 28 p. http://pubs.usgs.gov/pp/1787/p1787.pdf Zhu, Z., and B.C. Reed, eds., 2012, Baseline and projected future carbon storage and greenhouse-gas fluxes in ecosystems of the western United States: U.S. Geological Survey Professional Paper 1797, 191 p. http://pubs.usgs.gov/pp/1797/pdf/PP1797_WholeDocument.pdfZhu, Z., B. Bergamaschi, R. Bernknopf, D. Clow, D. Dye, S. Faulkner, W. Forney, R. Gleason, T. Hawbaker, J. Liu, S. Liu, S. Prisley, B. Reed, M. Reeves, M. Rollins, B. Sleeter, T. Sohl, S. Stackpoole, S. Stehman, R. Striegl, and A. Wein, 2010, A method for assessing carbon stocks, carbon sequestration, and greenhouse-gas fluxes in ecosystems of the United States under present conditions and future scenarios: U.S. Geological Survey Scientific Investigations Report 2010-5233, 187 p. http://pubs.usgs.gov/sir/2010/5233/pdf/sir2010-5233.pdf

Zielinski, R.A., and R.B. Finkelman, 1997, Radioactive elements in coal and fly ash: abundance, forms, and environmental significance: U.S. Geological Survey Fact Sheet FS-163-97, 4 p. (http://greenwood.cr.usgs.gov/energy/factshts/163-97/FS-163-97.html)

Zodrow, E.L., 1993, Oblique factor model of total coal sulfur, Sydney coalfield, Nova Scotia, Canada (upper Carboniferous): 12 th International Congress of Stratigraphy and Geology of the Carboniferous and Permian, Comptes Rendus, v. 1, p. 279-290.

Zodrow, E.L., N.S. Snigirevskaya, and C.A. Palmer, 2002, Paleoenvironments and carbonate processes in plant-tissue preservation of calcite coal balls: Donets Basin, Russia and Ukraine (middle Carboniferous), in L.V. Hills, C.M. Henderson, and E.W. Bamber, eds., Carboniferous and Permian of the World: Canadian Society of Petroleum Geologists Memoir 19, p. 393-411.

Zuber, M.D., 1998, Production characteristics and reservoir analysis of coalbed methane reservoirs, in P.C. Lyons, ed., Special issue: Appalachian coalbed methane: International Journal of Coal Geology, v. 38, p. 27-45.Zuber, M.D., 1999, The use of Monte Carlo analysis to evaluate prospective coalbed methane properties, in M. Mastalerz, M. Glikson, and S.D. Golding, eds., Coalbed methane: scientific, environmental and economic evaluation: Boston, Kluwer Academic Publishers, p. 55-66.

Zuber, M.D., V.A. Kuuskraa, and W.K. Sawyer, 1992, Optimizing well spacing and hydraulic-fracture design for economic recovery of coalbed methane, in Coalbed methane: Society of Petroleum Engineers, Reprint Series 35, p. 223-227.

C.T. Rightmire, G.E. Eddy, and J.N. Kirr, eds., Coalbed methane resources of the United States: AAPG Studies in Geology 17, p. 45-71.

C.T. Rightmire, G.E. Eddy, and J.N. Kirr, eds., Coalbed methane resources of the United States: AAPG Studies in Geology 17, p. 15-43.

ALL Consulting, 2003, Handbook on coal bed methane produced water: management and beneficial use alternatives: Coal bed methane resources and produced water management, U.S. Department of Energy, Office of Fossil Energy, National Energy Technology Laboratory, CD. (http://www.all-llc.com/CBM/BU/index.htm)

A.G. Douglas and J.R. Maxwell, eds., Advances in Organic Geochemistry 1979: New York, Pergamon Press, Physics and Chemistry of the Earth, v. 12, p. 599-618.

Alsaab, D., I. Suarez-Ruiz, M. Elie, A. Izart, and L. Martinez, 2007, Comparision of generative capacities for bitumen and gas between Carboniferous coals from Donets Basin (Ukraine) and a Cretaceous coal from Sabinas-Piedras Negras Basin (Mexico) during artificial maturation in confined pyrolysis system: International Journal of Coal Geology, v. 71, p. 85-102.

Alsaab, D., M. Elie, A. Izart, R.F. Sachsenhofer, V.A. Privalov, I. Suarez-Ruiz, L. Martinez, and E.A. Panova, 2009, Distribution of thermogenic methane in Carboniferous coal seams of the Donets Basin (Ukraine): "Applications to exploitation of methane and forecast of mining hazards": International Journal of Coal Geology, v. 78, p. 27-37.

S.D. Schwochow, D.K. Murray, and M.F. Fahy, eds., Coalbed methane of western North America: Denver, CO, Rocky Mountain Association of Geologists Guidebook, p. 227-240.

American Society for Testing and Materials (ASTM), 2011, Standard test method for microscopical determination of the reflectance of vitrinite dispersed in sedimentary rocks: West Conshohocken, PA, ASTM International, Annual book of ASTM standards: Petroleum products, lubricants, and fossil fuels; Gaseous fuels; coal and coke, sec. 5, v. 5.06, D7708-11, p. 823-830, doi: 10.1520/D7708-11, http://www.astm.org/Standards/D7708.htmAmerican Society for Testing and Materials (ASTM), 2014, Standard test method for microscopical determination of the reflectance of vitrinite dispersed in sedimentary rocks: West Conshohocken, PA, ASTM International, Annual book of ASTM standards: Petroleum products, lubricants, and fossil fuels; Gaseous fuels; coal and coke, sec. 5, v. 5.06, D7708-14, p. 823-830, doi: 10.1520/D7708-11, http://www.astm.org/Standards/D7708.htm

Angelone, M., C. Gasparini, M. Guerra, S. Lombardi, L. Pizzino, F. Quattrocchi, E. Sacchi, and G.M. Zuppi, 2005, Fluid geochemistry of the Sardinian Rift-Campidiano Graben (Sardinia, Italy): fault segmentation, seismic quiescence of geochemically "active" faults, and new constraints for selection of CO2 storage sites: Applied Geochemistry, v. 20, p. 317-340.

Araujo, C.V., A.G. Borrego, B. Cardott, R.B.A. das Chagas, D. Flores, P. Gonçalves, P.C. Hackley, J.C. Hower, M.L. Kern, J. Kus, M. Mastalerz, J.G.M. Filho, J.de Olivera Mendonça, T.R. Menezes, J. Newman, I. Suarez-Ruiz, F.S. da Silva, and I.V. de Souza, 2014, Petrographic maturity parameters of a Devonian shale maturation series, Appalachian Basin, USA. ICCP Thermal Indices Working Group interlaboratory exercise: International Journal of Coal Geology, v. 130, p. 89-101.

J.C. Hower and C.F. Eble, eds., Geology and petrology of Appalachian coals: International Journal of Coal Geology, v. 31, p. 151-167.

P. Lufholm and D. Cox, eds., 2005 WTGS Fall Symposium: West Texas Geological Society, Publication No. 05-115, p. 43-65. P. Lufholm and D. Cox, eds., 2005 WTGS Fall Symposium: West Texas Geological Society, Publication No. 05-115, p. 43-65.

P.K. Mukhopadhyay and W.G. Dow, eds., Vitrinite reflectance as a maturity parameter, applications and limitations: Washington, D.C., American Chemical Society, ACS. Symposium Series 570, p. 216-229. L.M.H. Carter, ed., USGS research on energy resources—1990 program and abstracts: U.S. Geological Survey Circular 1060, p. 6-8.

Barker, C.E., L.R. Biewick, P.D. Warwick, and J.R. SanFilipo, 2000, Preliminary Gulf Coast coalbed methane exploration maps; depth to Wilcox, apparent Wilcox thickness, and vitrinite reflectance: U.S. Geological Survey, Open-File Report 00-0113. (see http://greenwood.cr.usgs.gov/pub/open-file-reports/ofr-00-0113/wlcxmaps.htm)

W.R. Keefer and others, eds., Wyoming Geological Association special symposium on oil and gas and other resources of the Wind River basin, Wyoming: Casper, Wyoming Geological Association, p. 243-256.

M. Mastalerz, M. Glikson, and S.D. Golding, eds., Coalbed methane: scientific, environmental and economic evaluation: Boston, Kluwer Academic Publishers, p. 279-296.

Bechtel, A., R.F. Sachsenhofer, A. Zdravkov, I. Kostova, and R. Gratzer, 2005, Influence of floral assemblage, facies and diagenesis on petrography and organic geochemistry of the Eocene Bourgas coal and the Miocene Maritza-East lignite (Bulgaria): Organic Geochemistry, v. 36, p. 1498-1522. (uses groundwater index)

S.D. Schwochow, D.K. Murray, and M.F. Fahy, eds., Coalbed methane of western North America: Denver, CO, Rocky Mountain Association of Geologists Guidebook, p. 21-34.

P.K. Mukhopadhyay and W.G. Dow, eds., Vitrinite reflectance as a maturity parameter: applications and limitations: Washington, D.C., American Chemical Society Symposium Series 570, p. 39-51.

B. Durand and F. Behar, eds., Advances in organic geochemistry 1989, part II, molecular geochemistry: Organic Geochemistry, v. 16, p. 661-675.

Boak, J., 2008, Estimate of carbon dioxide production for in-situ production of shale oil from the Green River Formation in western Colorado: Proceedings of the 27th Oil Shale Symposium, Colorado Energy Research Institute Document 2008-1, Colorado School of Mines, Golden, CO (CD-ROM) http://www.ceri-mines.org/oilshaleresearch.htm

Bojesen-Koefoed, J.A., H.I. Petersen, F. Surlyk, and H. Vosgerau, 1997, Organic petrography and geochemistry of inertinite-rich mudstones, Jakobsstigen Formation, Upper Jurassic, northeast Greenland: indications of forest fires and variations in relative sea-level: International Journal of Coal Geology, v. 34, p. 345-370.

Borrego, A.G., C.V. Araujo, A. Balke, B. Cardott, A.C. Cook, P. David, D. Flores, M. Hámor-Vidó, W. Hiltmann, W. Kalkreuth, J. Koch, C.J. Kommeren, J. Kus, B. Ligouis, M. Marques, J.G. Mendoça Filho, M. Misz, L. Oliveira, W. Pickel, K. Reimer, P. Ranasinghe, I. Suárez-Ruiz, and A. Vieth, 2006, Influence of particle and surface quality on the vitrinite reflectance of dispersed organic matter: Comparative exercise using data from the qualifying system for reflectance analysis working group of ICCP: International Journal of Coal Geology, v. 68, p. 151-170.

B. Alpern, ed., Petrographie de la matiere organique des sediments, relations avec la paleotemperature et le potentiel petrolier: Paris, CNRS, p. 13-25. B. Alpern, eds., Petrographie de la matiere organique des sediments, relations avec la paleotemperature et le potentiel petrolier: Paris, CNRS, p. 13-25.

J. Woodward, F.F. Meissner, and J.L. Clayton, eds., Hydrocarbon source rocks of the greater Rocky Mountain Region: Denver, CO, Rocky Mountain Association of Geologists, p. 387-392.

Bragg, L.J., J.K. Oman, S.J. Tewalt, C.J. Oman, N.H. Rega, P.M. Washington, and R.B. Finkelman, 1998, U.S. Geological Survey coal quality (COALQUAL) database: U.S. Geological Survey Open-File Report 97-134, CD-ROM. http://pubs.usgs.gov/of/1997/of97-134/ http://energy.er.usgs.gov/products/databases/CoalQual/index.htm

Overview of coal and coalbed methane in the Cherokee basin, northeast Oklahoma: Fieldtrip guidebook for the First Coalbed Methane Symposium, Tulsa, Oklahoma, November, 9, 2004, Oklahoma Geological Survey and Kansas Geological Survey, p. 97-116. (Available as Kansas Geological Survey Open-file report 2004-49).

Brownfield, M.E., R.H. Affolter, J.D. Cathcart, S.Y. Johnson, I.K. Brownfield, and C.A. Rice, 2005, Geologic setting and characterization of coals and the modes of occurrence of selected elements from the Franklin coal zone, Puget Group, John Henry No. 1 mine, King County, Washington, USA: International Journal of Coal Geology, v. 63, p. 247-275.

Brownfield, M.E., J.G. Self, and T.J. Mercier, 2011, Fischer Assay histograms of oil-shale drill cores and rotary cuttings from the Great Divide, Green River, and Washakie Basins, southwestern Wyoming: U.S. Geological Survey, Digital Data Series DDS-69-DD, chapter 6, 9 p. http://pubs.usgs.gov/dds/dds-069/dds-069-dd/REPORTS/69_DD_CH_6.pdf

on coals by high pressure adsorption/desorption experiments with gas mixtures: Tuscaloosa, Alabama, University of Alabama, College of Continuing Studies, 2003 International Coalbed Methane Symposium Proceedings, paper 0350, 14 p. W.L. Watney, R.L. Kaesler, and K.D. Newell, conveners, Recent interpretations of late Paleozoic cyclothems: Midcontinent SEPM Proceedings of Third Annual Meeting and Field Conference, p. 141-153.

J.C. Cobb and C.B. Cecil, eds., Modern and ancient coal-forming environments: Geological Society of America Special Paper 286, p. 153-180.

P. Bertrand, ed., Coal: formation, occurrence and related properties: Bulletin de la Societe Geologique de France, v. 162, p. 283-298.

F. Goodarzi and R.W. Macqueen, eds., Geochemistry and petrology of bitumen with respect to hydrocarbon generation and mineralization: Energy Sources, v. 15, p. 239-267. F. Goodarzi and R.W. Macqueen, eds., Geochemistry and petrology of bitumen with respect to hydrocarbon generation and mineralization: Energy Sources, v. 15, p. 239-267.

Annual GCSSEPM Foundation Bob F. Perkins Research Conference, CD-ROM, p. 388-395. sequestration potential of coalbed methane reservoirs in the Black Warrior basin: Tuscaloosa, Alabama, University of Alabama College of Continuing Studies, 2003 International Coalbed Methane Symposium Proceedings, Paper 0317, 11 p.

R.R. Dutcher, P.A. Hacquebard, J.M. Schopf, and J.A. Simon, eds., Carbonaceous materials as indicators of metamorphism: GSA Special Paper 153, p. 31-52. R.R. Dutcher, P.A. Hacquebard, J.M. Schopf, and J.A. Simon, eds., Carbonaceous materials as indicators of metamorphism: Geological Society of America Special Paper 153, p. 31-52.

S.D. Schwochow, D.K. Murray, and M.F. Fahy, eds., Coalbed methane of western North America: Denver, CO, Rocky Mountain Association of Geologists Guidebook, p. 155-162.

J.C. Cobb and C.B. Cecil, eds., Modern and ancient coal-forming environments: Geological Society of America Special Paper 286, p. 3-22.

T.L. Phillips and C.B. Cecil, eds., Paleoclimate controls on coal resources of the Pennsylvanian System of North America: International Journal of Coal Geology, v. 5, p. 195-230.

Petroleum Geology Conference, p. 1171-1182.

J.B. Roen and R.C. Kepferle, eds., Petroleum geology of the Devonian and Mississippian black shale of eastern North America: U.S. Geological Survey Bulletin 1909, p. N1-N14.

Clarkson, C.R., M.N. Lamberson, and R.M. Bustin, 1993, Variation in surface area and micropore size distribution with composition of medium volatile bituminous coal of the Gates Formation, northeastern British Columbia: implications for coalbed methane potential: Current Research, Part E, Geological Survey of Canada Paper 93-1, p. 97-104.

J.E. Fassett, ed., Geology and coal-bed methane resources of the northern San Juan basin, Colorado and New Mexico: Denver, Rocky Mountain Association of Geologists Guidebook, p. 125-132.

D.G. Howell, ed., The future of energy gases: U.S. Geological Survey Professional Paper 1570, p. 471-492.

P.K. Mukhopadhyay, M.G. Fowler, and W.G. Dow, eds., Selected papers from the symposium on coal and terrestrial organic matter as a source rock for petroleum: Organic Geochemistry, v. 17, p. 735-742.

Cohen, A.D., and A.M. Bailey, 1997, Petrographic changes induced by artificial coalfication of peat: comparison of two planar facies (Rhizophora and Cladium) from the Everglades-Mangrove complex of Florida and a dome facies (Cyrilla) from the Okefenokee Swamp of Georgia: International Journal of Coal Geology, v. 34, p. 163-194. R.A. Rahmani and R.M. Flores, eds., Sedimentology of coal and coal-bearing sequences: International Association of Sedimentologists, Special Publication 7, Boston, Blackwell Scientific Publications, p. 231-240.

A.C. Scott, ed., Coal and coal-bearing strata: recent advances: London, Geological Society Special Publication 32, Boston, Blackwell Scientific Publications, p. 107-125.

A.C. Scott and A.J. Fleet, eds., Coal and coal-bearing strata as oil-prone source rocks?: London, The Geological Society Special Publication 77, p. 31-70.

A.G. Douglas and J.R. Maxwell, eds., Advances in Organic Geochemistry 1979: New York, Pergamon Press, Physics and Chemistry of the Earth, v. 12, p. 663-677.

R.L. Langenheim, Jr., and C.J. Mann, eds., Middle and Late Pennsylvanian strata on margin of Illinois basin, Vermilion County, Illinois and Vermillion and Parke Counties, Indiana: SEPM Great Lakes Section, Tenth Annual Field Conference, p. 93-104.

Cutruneo, C.M.N.L., M.L.S. Oliveira, C.R. Ward, J.C. Hower, I.A.S. de Brum, C.H. Sampaio, R.M. Kautzmann, S.R. Taffarel, E.C. Teixeira, and L.F.O. Silva, 2014, A mineralogical and geochemical study of three Brazilian coal cleaning rejects: Demonstration of electron beam applications: International Journal of Coal Geology, v. 130, p. 33-52.Cutruneo, C.M.N.L., M.L.S. Oliveira, C.R. Ward, J.C. Hower, I.A.S. de Brum, C.H. Sampaio, R.M. Kautzmann, S.R. Taffarel, E.C. Teixeira, and L.F.O. Silva, 2014, A mineralogical and geochemical study of three Brazilian coal cleaning rejects: Demonstration of electron beam applications: International Journal of Coal Geology, v. 130, p. 33-52.

P.K. Mukhopadhyay, M.G. Fowler, and W.G. Dow, eds., Selected papers from the symposium on coal and terrestrial organic matter as a source rock for petroleum: Organic Geochemistry, v. 17, p. 785-803.

A.C. Scott and A.J. Fleet, eds., Coal and coal-bearing strata as oil-prone source rocks?: London, The Geological Society Special Publication 77, p. 149-181.

Dai, S., J. Zou, Y. Jiang, C.R. Ward, X. Wang, T. Li, W. Xue, S. Liu, H. Tian, X. Sun, and D. Zhou, 2012, Mineralogical and geochemical compositions of the Pennsylvanian coal in the Adaohai mine, Daqingshan Coalfield, Inner Mongolia, China: Modes of occurrence and origin of diaspora, gorceixite, and ammonian illite: International Journal of Coal Geology, v. 94, p. 250-270.Dai, S., J. Zou, Y. Jiang, C.R. Ward, X. Wang, T. Li, W. Xue, S. Liu, H. Tian, X. Sun, and D. Zhou, 2012, Mineralogical and geochemical compositions of the Pennsylvanian coal in the Adaohai mine, Daqingshan Coalfield, Inner Mongolia, China: Modes of occurrence and origin of diaspora, gorceixite, and ammonian illite: International Journal of Coal Geology, v. 94, p. 250-270.Dai, S., L. Tian, C.-L. Chou, Y. Zhou, M. Zhang, L. Zhao, J. Wang, Z. Yang, H. Cao, and D. Ren, 2008, Mineralogical and compositional characteristics of Late Permian coals from an area of high lung cancer rate in Xuan Wei, Yunnan, China: Occurrence and origin of quartz and chamosite: International Journal of Coal Geology, v. 76, p. 318-327.

Dai, S., V.V. Seredin, C.R. Ward, J. Jiang, J.C. Hower, X. Song, Y. Jiang, X. Wang, T. Gornostaeva, X. Li, H. Liu, L. Zhao, and C. Zhao, 2014, Composition and modes of occurrence of minerals and elements in coal combustion products derived from high-Ge coals: International Journal of Coal Geology, v. 121, p. 79-97. (Germanium)

Dai, S., W. Zhang, C.R. Ward, V.V. Seredin, J.C. Hower, X. Li, W. Song, X. Wang, H. Kang, L. Zheng, P. Wang, and D. Zhou, 2013, Mineralogical and geochemical anomalies of late Permian coals from the Fusui coalfield, Guangxi Province, southern China: Influences of terrigenous materials and hydrothermal fluids: International Journal of Coal Geology, v. 105, p. 60-84.Dai, S., W. Zhang, V.V. Seredin, C.R. Ward, J.C. Hower, W. Song, X. Wang, X. Li, L. Zhao, H. Kang, L. Zheng, P. Wang, and D. Zhou, 2013, Factors controlling geochemical and mineralogical compositions of coals preserved within marine carbonate successions: A case study from the Heshan coalfield, southern China: International Journal of Coal Geology, v. 109-110, p. 77-100.

Dai, S., X. Wang, V.V. Seredin, J.C. Hower, C.R. Ward, J.M.K. O’Keefe, W. Huang, T. Li, X. Li, H. Liu, W. Xue, and L. Zhao, 2012, Petrology, mineralogy, and geochemistry of the Ge-rich coal from the Wulantuga Ge ore deposit, Inner Mongolia, China: New data and genetic implications: International Journal of Coal Geology, v. 90-91, p. 72-99. (Germanium) [erratum in International Journal of Coal Geology, v. 105, p. 141]Dai, S., X. Wang, W. Chen, D. Li, C-L. Chou, Y. Zhou, C. Zhu, H. Li, X. Zhu, Y. Xing, W. Zhang, and J. Zou, 2010, A high-pyrite semianthracite of Late Permian age in the Songzao coalfield, southwestern China: mineralogical and geochemical relations with underlying mafic tuffs: International Journal of Coal Geology, v. 83, p. 430-445.Dai, S., Y. Jiang, C.R. Ward, L. Gu, V.V. Seredin, H. Liu, D. Zhou, X. Wang, Y. Sun, J. Zou, and D. Ren, 2012, Mineralogical and geochemical compositions of the coal in the Guanbanwusu mine, Inner Mongolia, China: Further evidence for the existence of an Al (Ga and REE) ore deposit in the Jungar coalfield: International Journal of Coal Geology, v. 98, p. 10-40.Dai, S., Y. Jiang, C.R. Ward, L. Gu, V.V. Seredin, H. Liu, D. Zhou, X. Wang, Y. Sun, J. Zou, and D. Ren, 2012, Mineralogical and geochemical compositions of the coal in the Guanbanwusu mine, Inner Mongolia, China: Further evidence for the existence of an Al (Ga and REE) ore deposit in the Jungar coalfield: International Journal of Coal Geology, v. 98, p. 10-40.

Dai, S., Y. Zhou, M. Zhang, X. Wang, J. Wang, X. Song, Y. Jiang, Y. Luo, Z. Song, Z> Yang, and D. Ren, 2010, A new type of Nb (Ta) – Zr (HF) – REE – Ga polymetallic deposit in the late Permian coal-bearing strata, eastern Yunnan, southwestern China: Possible economic significance and genetic implications: International Journal of Coal Geology, v. 83, p. 55-63.

Davies, R., C. Diessel, J. Howell, S. Flint, and R. Boyd, 2005, Vertical and lateral variation in the petrography of the Upper Cretaceous Sunnyside coal of eastern Utah, USA—implications for the recognition of high-resolution accommodation changes in paralic coal seams: International Journal of Coal Geology, v. 61, p. 13-33.

J.E. Fassett, ed., Geology and coal-bed methane resources of the northern San Juan basin, Colorado and New Mexico: Denver, Rocky Mountain Association of Geologists Guidebook, p. 221-235.

C.B. Eckardt, J.R. Maxwell, S.R. Larter, and D.A.C. Manning, eds., Advances in organic geochemistry 1991, part II. Advances and applications in energy and the natural environment: Organic Geochemistry, v. 19, p. 345-350. C.B. Eckardt, J.R. Maxwell, S.R. Larter, and D.A.C. Manning, eds., Advances in organic geochemistry 1991, part II. Advances and applications in energy and the natural environment: Organic Geochemistry, v. 19, p. 299-313.

S.D. Schwochow, D.K. Murray, and M.F. Fahy, eds., Coalbed methane of western North America: Denver, CO, Rocky Mountain Association of Geologists Guidebook, p. 287-295.

A.T. Cross, ed., Economic geology: coal, oil and gas: Neuvieme Congres International de Stratigraphie et du Geologie du Carbonifere, Compte Rendu, v. 4, Southern Illinois University Press, p. 573-580.

L.V. Hills, C.M. Henderson, and E.W. Bamber, eds., Carboniferous and Permian of the World: XIV ICCP Proceedings: Canadian Society of Petroleum Geologists Memoir 19, p. 851-867.

Dressel, B., and D. Olsen, 2010, Geologic storage formation classifications: understanding its importance and impacts on CCS opportunities in the United States: U.S. Department of Energy, National Energy Technology Laboratory, 56 p. http://www.fe.doe.gov/news/techlines/2010/10050-Geologic_Storage_Manual_Issued.html

J. Schieber and R. Lazar, eds., Devonian black shales of the eastern U.S.: New insights into sedimentology and stratigraphy from the subsurface and outcrops in the Illinois and Appalachian Basins: Indiana Geological Survey Open-File Study 04-05, p. 61-67.

Dutta, S., R.P. Mathews, B.D. Singh, S.M. Tripathi, A. Singh, P.K. Saraswati, S. Banerjee, and U. Mann, 2011, Petrology, palynology and organic geochemistry of Eocene lignite of Matanomadh, Kutch Basin, western India: Implications to depositional environment and hydrocarbon source potential: International Journal of Coal Geology, v. 85, p. 91-102.Dutta, S., R.P. Mathews, B.D. Singh, S.M. Tripathi, A. Singh, P.K. Saraswati, S. Banerjee, and U. Mann, 2011, Petrology, palynology and organic geochemistry of Eocene lignite of Matanomadh, Kutch Basin, western India: Implications to depositional environment and hydrocarbon source potential: International Journal of Coal Geology, v. 85, p. 91-102.

Engle, M.A., L.F. Radke, E.L. Heffern, J.M.K. O’Keefe, C.D. Smeltzer, J.C. Hower, J.M. Hower, A. Prakash, A. Kolker, R.J. Eatwell, A. ter Schure, G. Queen, K.L. Aggen, G.B. Stracher, K.R. Henke, R.A. Olea, and Y. Román-Colón, 2011, Quantifying greenhouse gas emissions from coal fires using airborne and ground-based methods: International Journal of Coal Geology, v. 88, p. 147-151.

J.E. Fassett, ed., Geology and coal-bed methane resources of the northern San Juan basin, Colorado and New Mexico: Denver, Rocky Mountain Association of Geologists Guidebook, p. 155-158.

Fabiańska, M.J., J. Ciesielczuk, Ł. Kruszewski, M. Misz-Kennan, D.R. Blake, G. Stracher, and I. Moszumańska, 2013, Gaseous compounds and effluorescences generated in self-heating coal-waste dumps—A case study from the Upper and Lower Silesian coal basins (Poland): International Journal of Coal Geology, v. 116-117, p. 247-261.

B.A. Vining and S.C. Pickering, eds., Petroleum geology: from mature basins to new frontiers: London, Geological Society, Proceedings of the 7 th Petroleum Geology Conference, p. 1189-1195.

M.G. Bishop, S.P. Cumella, J.W. Robinson, and M.R. Silverman, eds., Gas in low-permeability reservoirs of the Rocky Mountain region: Rocky Mountain Association of Geologists 2005 Guidebook, p. 109-185.

N. Telnaes, and others, eds., Advances in organic geochemistry 1993: Organic Geochemistry, v. 22, p. 759-771.

L.M. Carter, ed., Proceedings of the fourth symposium on the geology of Rocky Mountain coal–1980: Colorado Geological Survey Resource Series 10, p. 17-20.

F. Goodarzi and R.W. Macqueen, eds., Geochemistry and petrology of bitumen with respect to hydrocarbon generation and mineralization: Energy Sources, v. 15, p. 315-337. P.K. Mukhopadhyay, M.G. Fowler, and W.G. Dow, eds., Selected papers from the symposium on coal and terrestrial organic matter as a source rock for petroleum: Organic Geochemistry, v. 17, p. 681-694.

D.G. Howell, ed., The future of energy gases: USGS Professional Paper 1570, p. 405-437.

C.J. Cobb and C.B. Cecil, eds., Modern and ancient coal-forming environments: Geological Society of America Special Paper 286, p. 107-118. J.C. Pashin and R.A. Gastaldo, eds., Sequence stratigraphy, paleoclimate, and tectonics of coal-bearing strata: AAPG Studies in Geology 51, p. 219-238.

Gentzis, T., A. Iacchelli, H. Whaley, D.P. Deshpande, and B. Ozüm, 1996, Combustion reactivity of Smoky River coal mine by-products: Energy Sources, v. 18, p. 151-166. "Combustion efficiency could be improved by increasing turbulence intensity in the furnace, by blending the coal with a more reactive fuel, or by reducing the ash content of the coal"

J.C. Pashin and R.A. Gastaldo, eds., Sequence stratigraphy, paleoclimate, and tectonics of coal-bearing strata: AAPG Studies in Geology 51, p. 169-197.

D.I. Gravestock, P.S. Moore, and G.M. Pitt, eds., Contributions to the geology and hydrocarbon potential of the Eromanga basin: Geological Society of Australia Special Publication 12, p. 273-286. M. Mastalerz, M. Glikson, and S.D. Golding, eds., Coalbed methane: scientific, environmental and economic evaluation: Boston, Kluwer Academic Publishers, p. 155-185. (bitumen) M. Mastalerz, M. Glikson, and S.D. Golding, eds., Coalbed methane: scientific, environmental and economic evaluation: Boston, Kluwer Academic Publishers, p. 155-185. (bitumen)

M. Mastalerz, M. Glikson, and S.D. Golding, eds., Coalbed methane: scientific, environmental and economic evaluation: Boston, Kluwer Academic Publishers, p. 257-269.(carbon isotope composition)

N.B. Harris and K.E. Peters, eds., Analyzing the thermal history of sedimentary basins: Methods and case studies: SEPM Special Publication 103, p. 167-186.

F. Goodarzi and R.W. Macqueen, eds., Geochemistry and petrology of bitumen with respect to hydrocarbon generation and mineralization: Energy Sources, v. 15, p. 177-180.

Goodman, A.L., A. Busch, G.J. Duffy, J.E. Fitzgerald, K.A.M. Gasem, Y. Gensterblum, B.M. Krooss, J. Levy, E. Ozdemir, Z. Pan, R.L. Robinson, Jr., K. Schroeder, M. Sudibandriyo, and C. White, 2004, An inter-laboratory comparison of CO2 isotherms measured on Argonne premium coal samples: Energy and Fuels, v. 18, p. 1175-1182.Goodman, A.L., A. Busch, G.J. Duffy, J.E. Fitzgerald, K.A.M. Gasem, Y. Gensterblum, B.M. Krooss, J. Levy, E. Ozdemir, Z. Pan, R.L. Robinson, Jr., K. Schroeder, M. Sudibandriyo, and C. White, 2004, An inter-laboratory comparison of CO2 isotherms measured on Argonne premium coal samples: Energy and Fuels, v. 18, p. 1175-1182.Goodman, A.L., A. Busch, R.M. Bustin, L. Chikatamarla, S. Day, G.J. Duffy, J.E. Fitzgerald, K.A.M. Gasem, Y. Gensterblum, C. Hartman, C. Jing, B.M. Krooss, S. Mohammed, T. Pratt, R.L. Robinson, Jr., V. Romanov, R. Sakurovs, K. Schroeder, and C.M. White, 2007, Inter-laboratory comparison II: CO2 isotherms measured on moisture-equilibrated Argonne premium coals at 55°C and up to 15 MPa: International Journal of Coal Geology, v. 72, p. 153-164. (see Yu et al., 2008 for comment)

M. Schidlowski et al., eds., Early organic evolution: implications for mineral and energy resources: New York, Springer-Verlag, p. 279-295.

F. Goodarzi and R.W. Macqueen, eds., Geochemistry and petrology of bitumen with respect to hydrocarbon generation and mineralization: Energy Sources, v. 15, p. 339-357. F. Goodarzi and R.W. Macqueen, eds., Geochemistry and petrology of bitumen with respect to hydrocarbon generation and mineralization: Energy Sources, v. 15, p. 359-376.

J.C. Cobb and C.B. Cecil, eds., Modern and ancient coal-forming environments: Geological Society of America Special Paper 286, p. 63-82. J.C. Cobb and C.B. Cecil, eds., Modern and ancient coal-forming environments: GSA Special Paper 286, p. 63-82.

Groshong, R. H., Jr., M. H. Cox, J. C. Pashin, and M. R. McIntyre, 2003, Relationship between gas and water production and structure in southeastern Deerlick Creek coalbed methane field, Black Warrior basin, Alabama: Tuscaloosa, Alabama, University of Alabama College of Continuing Studies, 2003 International Coalbed Methane Symposium Proceedings, Paper 0306, 12 p.

J.C. Pashin and R.A. Gastaldo, eds., Sequence stratigraphy, paleoclimate, and tectonics of coal-bearing strata: AAPG Studies in Geology 51, p. 89-120.

M.A. Chan and A.W. Archer, eds., Extreme depositional environments: Mega end members in geologic time: Geological Society of America Special Paper 370, p. 127-150.

M. Mastalerz, M. Glikson, and S.D. Golding, eds., Coalbed methane: scientific, environmental and economic evaluation: Boston, Kluwer Academic Publishers, p. 493-515.

P.K. Mukhopadhyay, M.G. Fowler, and W.G. Dow, eds., Selected papers from the symposium on coal and terrestrial organic matter as a source rock for petroleum: Organic Geochemistry, v. 17, p. 839-847.

Proceedings of the IX International Palynological Congress, Houston, Texas, U.S.A., 1996: American Association of Stratigraphic Palynologists, p. 79-97.

T.D. Fouch, V.F. Nuccio, and T.C. Chidsey, Jr., eds., Hydrocarbon and mineral resources of the Uinta basin, Utah and Colorado: Salt Lake City, Utah Geological Association, Guidebook 20, p. 271-287.

Havelcová, M., I. Sýkorová, A. Bechtel, K. Mach, H. Trejtnarová, M. Žaloudková, P. Matysová, J. Blažek, J. Boudová, and J. Sakala, 2013, "Stump horizon" in the Bílina mine (Most Basin, Czech Republic) — GC–MS, optical and electron microscopy in identification of wood biological origin: International Journal of Coal Geology, v. 107, p. 62-77.

Helms, J.R., X. Kong, E. Salmon, P.G. Hatcher, K. Schmidt-Rohr, and J. Mao, 2012, Structural characterization of gilsonite bitumen by advanced nuclear magnetic resonance spectroscopy and ultrahigh resolution mass spectrometry revealing pyrrolic and aromatic rings substituted with aliphatic chains: Organic Geochemistry, v. 44, p. 21-36.

E.S. Belt and R.W. Macqueen, eds., Sedimentology and geochemistry, part 3: Neuvieme Congress International de Stratigraphie et de Geologie du Carbonifere, Southern Illinois University Press, Compte Rendu, v. 3, p. 535-553.

J.M. Dennison and F.R. Ettensohn, eds., Tectonic and eustatic controls on sedimentary cycles: SEPM Concepts in Sedimentology and Paleontology, v. 4, p. 65-87. L.V. Hills, C.M. Henderson, and E.W. Bamber, eds., Carboniferous and Permian of the World: Canadian Society of Petroleum Geologists Memoir 19, p. 99-119.

Petroleum Geology Conference, p. 1183-1188.

L. Mattavelli and L. Novelli, eds., Advances in organic geochemistry 1987, part I, organic geochemistry in petroleum exploration: Organic Geochemistry, v. 13, p. 121-129.

International Symposium on Use and Management of Coal Combustion Products, p. 28-1 to 28-10.

Hower, J.C., J.M.K. O’Keefe, C.F. Eble, A. Raymond, B. Valentim, T.J. Volk, A.R. Richardson, A.B. Satterwhite, R.S. Hatch, J.D. Stucker, and M.A. Watt, 2011, Notes on the origin of inertinite macerals in coal: Evidence for fungal and arthropod transformations of degraded macerals: International Journal of Coal Geology, v. 86, p. 231-240. [erratum, International Journal of Coal Geology, v. 116-117, p. 182.]Hower, J.C., J.M.K. O’Keefe, C.F. Eble, T.J. Volk, A.R. Richardson, A.B. Satterwhite, R.S. Hatch, and I.J. Kostova, 2011, Notes on the origin of inertinite macerals in coals: Funginite associations with cutinite and suberinite: International Journal of Coal Geology, v. 85, p. 186-190. [erratum, International Journal of Coal Geology, v. 116-117, p. 182.]

Hower, J.C., J.M.K. O’Keefe, K.R. Henke, N. J. Wagner, G. Copley, D.R. Blake, T. Garrison, M.L.S. Oliveira, R.M. Kautzmann, and L.F.O. Silva, 2013, Gaseous emissions and sublimates from the Truman Shepherd coal fire, Floyd County, Kentucky: A re-investigation following attempted mitigation of the fire: International Journal of Coal Geology, v. 116-117, p. 63-74.

International Symposium on use and management of coal combustion by-products: American Coal Ash Association, p. 62-1 to 62-12.

S.-H. Chiang, ed., Coal — energy and the environment: Tenth Annual International Pittsburgh Coal Conference, Proceedings, p. 1022-1025.

Huggins, F.E., L.B.A. Seidu, N. Shah, G.P. Huffman, R.Q. Honaker, J.R. Kyger, B.L. Higgins, J.D. Robertson, S. Pal, and M.S. Seehra, 2009, Elemental modes of occurrence in an Illinois #6 coal and fractions prepared by physical separation techniques at a coal preparation plant: International Journal of Coal Geology, v. 78, p. 65-76.

International Symposium on Coal Combustion By-Product (CCB) Management and Use: Electric Power Research Institute, p. 39-1 to 39-13.

E.L. Fuller, Jr., ed., Coal and coal products: analytical characterization techniques: Washington, D.C., American Chemical Society, ACS Symposium Series 205, p. 239-258.

C.W. Mallett, ed., Coal resources: origin, exploration and utilization in Australia, Proceedings: Geological Society of Australia Coal Group, Symposium, p. 484-502. R.A. Rahmani and R.M. Flores, eds., Sedimentology of coal and coal-bearing sequences: Oxford, Blackwell Scientific, International Association of Sedimentologists, Special Publication 7, p. 61-84. R.A. Rahmani and R.M. Flores, eds., Sedimentology of coal and coal-bearing sequences: Boston, Blackwell Scientific Publications, International Association of Sedimentologists, Special Publication 7, p. 43-60.

Jasper, K., B.M. Krooss, G. Flajs, C. Hartkopf-Fröder, and R. Littke, 2009, Characteristics of type III kerogen in coal-bearing strata from the Pennsylvanian (Upper Carboniferous) in the Ruhr Basin, western Germany: Comparison of coals, dispersed organic matter, kerogen concentrates and coal-mineral mixtures: International Journal of Coal Geology, v. 80, p. 1-19.Jasper, K., B.M. Krooss, G. Flajs, C. Hartkopf-Fröder, and R. Littke, 2009, Characteristics of type III kerogen in coal-bearing strata from the Pennsylvanian (Upper Carboniferous) in the Ruhr Basin, western Germany: Comparison of coals, dispersed organic matter, kerogen concentrates and coal-mineral mixtures: International Journal of Coal Geology, v. 80, p. 1-19.Jasper, K., B.M. Krooss, G. Flajs, C. Hartkopf-Fröder, and R. Littke, 2009, Characteristics of type III kerogen in coal-bearing strata from the Pennsylvanian (Upper Carboniferous) in the Ruhr Basin, western Germany: Comparison of coals, dispersed organic matter, kerogen concentrates and coal-mineral mixtures: International Journal of Coal Geology, v. 80, p. 1-19.

Annual GCSSEPM Foundation Bob F. Perkins Research Conference, CD-ROM, p. 282-302.

Petroleum Geology Conference, p. 1061-1063.Johnson, H.R., P.M. Crawford, and J.W. Bunger, 2004, Strategic significance of America’s oil shale resource, v. 2, Oil shale resources, technology, and economics: U.S. Department of Energy Office of Naval Petroleum and Oil Shale Reserves, 57 p. http://www.fe.doe.gov/programs/reserves/publications/Pubs-NPR/npr_strategic_significancev2.pdfJohnson, H.R., P.M. Crawford, and J.W. Bunger, 2004, Strategic significance of America’s oil shale resource, v.1, Assessment of strategic issues: U.S. Department of Energy Office of Naval Petroleum and Oil Shale Reserves, 45 p. http://www.fe.doe.gov/programs/reserves/publications/Pubs-NPR/npr_strategic_significancev1.pdf

W.R. Keefer and others, eds., Wyoming Geological Association special symposium on oil and gas and other resources of the Wind River basin, Wyoming: Casper, Wyoming Geological Association, p. 215-242. W.R. Keefer and others, eds., Wyoming Geological Association special symposium on oil and gas and other resources of the Wind River basin, Wyoming: Casper, Wyoming Geological Association, p. 319-335.

W.R. Keefer and others, eds., Wyoming Geological Association special symposium on oil and gas and other resources of the Wind River basin, Wyoming: Casper, Wyoming Geological Association, p. 281-294. R.M. Flores, ed., Coalbed methane: from coal-mine outbursts to a gas resource: International Journal of Coal Geology, v. 35, p. 241-282.

S.D. Schwochow, D.K. Murray, and M.F. Fahy, eds., Coalbed methane of western North America: Denver, CO, Rocky Mountain Association of Geologists Guidebook, p. 273-284.

Johnson, R.C., T.J. Mercier, M.E. Brownfield, and J.G. Self, 2010, Assessment of in-place oil shale resources in the Eocene Green River Formation, Uinta Basin, Utah and Colorado: U.S. Geological Survey, Digital Data Series DDS-69-BB, chapter 1, 162 p. http://pubs.usgs.gov/dds/dds-069/dds-069-bb/REPORTS/69_BB_CH_1.pdf

Johnson, R.C., T.J. Mercier, M.E. Brownfield, M.P. Pantea, and J.G. Self, 2010, An assessment of in-place oil shale resources in the Green River Formation, Piceance Basin, Colorado: U.S. Geological Survey, Digital Data Series DDS-69-Y, chapter 1, 197 p. http://pubs.usgs.gov/dds/dds-069/dds-069-y/REPORTS/69_Y_CH_1.pdfJohnson, R.C., T.J. Mercier, R.T. Ryder, M.E. Brownfield, and J.G. Self, 2011, Assessment of in-place oil shale resources of the Eocene Green River Formation, Greater Green River Basin, Wyoming, Colorado, and Utah: U.S. Geological Survey, Digital Data Series DDS-69-DD, chapter 1, 68 p. http://pubs.usgs.gov/dds/dds-069/dds-069-dd/REPORTS/69_DD_CH_1.pdf

J.E. Fassett, ed., Geology and coal-bed methane resources of the northern San Juan basin, Colorado and New Mexico: Denver, Rocky Mountain Association of Geologists Guidebook, p. 169-181.

Jung, H.B., S. Kabilan, J.P. Carson, A.P. Kuprat, W. Um, P. Martin, M. Dahl, Y. Kafentzis, T. Varga, S. Stephens, B. Arey, K.C. Carroll, A. Bonneville, and C.A. Fernandez, 2014, Wellbore cement fracture evolution at the cement-basalt caprock interface during geologic carbon sequestration: Applied Geochemistry, v. 47, p. 1-16.

Kalkreuth, W., M. Lunkes, J. Oliveira, M.L. Ghiggi, E. Osório, K. Souza, C.H. Sampaio, and G. Hidalgo, 2013, The lower and upper coal seams of the Candiota coalfield, Brazil—Geological setting, petrological and chemical characterization, and studies on reactivity and beneficiation related to their combustion potential: International Journal of Coal Geology, v. 111, p. 53-66.

P.C. Lyons and B. Alpern, eds., Peat and coal: origin, facies and depositional models: International Journal of Coal Geology, v. 12, p. 381-424.

P.K. Mukhopadhyay, M.G. Fowler, and W.G. Dow, eds., Selected papers from the symposium on coal and terrestrial organic matter as a source rock for petroleum: Organic Geochemistry, v. 17, p. 711-722.

Kelemen, S.R., C.C. Walters, P.J. Kwiatek, H. Freund, M. Afeworki, M. Sansone, W.A. Lamberti, R.J. Pottorf, H.G. Machel, K.E. Peters, and T. Bolin, 2010, Characterization of solid bitumens originating from thermal chemical alteration and thermochemical sulfate reduction: Geochimica et Cosmochimica Acta, v. 74, p. 5305-5332.

S.D. Schwochow, D.K. Murray, and M.F. Fahy, eds., Coalbed methane of western North America: Denver, CO, Rocky Mountain Association of Geologists Guidebook, p. 201-208.

J.E. Fassett, ed., Geology and coal-bed methane resources of the northern San Juan basin, Colorado and New Mexico: Denver, Rocky Mountain Association of Geologists Guidebook, p. 257-279.

F. Goodarzi and R.W. Macqueen, eds., Geochemistry and petrology of bitumen with respect to hydrocarbon generation and mineralization: Energy Sources, v. 15, p. 181-204.

C.B. Eckardt, J.R. Maxwell, S.R. Larter, and D.A.C. Manning, eds., Advances in organic geochemistry 1991, part II. advances and applications in energy and the natural environment: Organic Geochemistry, v. 19, p. 327-343.

F. Goodarzi and R.W. Macqueen, eds., Geochemistry and petrology of bitumen with respect to hydrocarbon generation and mineralization: Energy Sources, v. 15, p. 181-204.

Current research, part G: Geological Survey of Canada, Paper 89-1G, p. 51-55.

J.M. Dennison and F.R. Ettensohn, eds., Tectonic and eustatic controls on sedimentary cycles: SEPM Concepts in Sedimentology and Paleontology, v. 4, p. 35-50.

J. Day and B.J. Bunker, eds., The stratigraphy, paleontology, depositional and diagenetic history of the Middle-Upper Devonian Cedar Valley Group of central and eastern Iowa: Iowa Geological Survey Guidebook 16, p. 147-158.

M. Podemski, S. Dybova-Jachowicz, K. Jaworowski, J. Jureczka, and R. Wagner, eds., Proceedings of the XIII International Congress on the Carboniferous and Permian: Warsaw, Polish Geological Institute, Prace, v. 157, pt. 2, p. 183-192.

Krzesińska, M., U. Szeluga, Ł. Smędowski, J. Majewska, S. Pusz, S. Czajkowska, and B. Kwiecińska, 2010, TGA and DMA studies of blends from very good coking Zofiówka coal and various carbon additives: weakly coking coals, industrial coke and carbonized plants: International Journal of Coal Geology, v. 81, p. 293-300.

B. Durand and F. Behar, eds., Advances in organic geochemistry 1989, part II, molecular geochemistry: Organic Geochemistry, v. 16, p. 689-701.

M. Podemski, S. Dybova-Jachowicz, K. Jaworowski, J. Jureczka, and R. Wagner, eds., Proceedings of the XIII International Congress on the Carboniferous and Permian: Warsaw, Polish Geological Institute, Prace, v. 157, pt. 2, p. 233-238. M. Podemski, S. Dybova-Jachowicz, K. Jaworowski, J. Jureczka, and R. Wagner, eds., Proceedings of the XIII International Congress on the Carboniferous and Permian: Warsaw, Polish Geological Institute, Prace, v. 157, pt. 2, p. 233-238.

M. Mastalerz, M. Glikson, and S.D. Golding, eds., Coalbed methane: scientific, environmental and economic evaluation: Boston, Kluwer Academic Publishers, p. 545-553.

J.C. Pashin and R.A. Gastaldo, eds., Sequence stratigraphy, paleoclimate, and tectonics of coal-bearing strata: AAPG Studies in Geology 51, p. 71-88. in J.C. Pashin and R.A. Gastaldo, eds., Sequence stratigraphy, paleoclimate, and tectonics of coal-bearing strata: AAPG Studies in Geology 51, p.

N.B. Harris and K.E. Peters, eds., Analyzing the thermal history of sedimentary basins: Methods and case studies: SEPM Special Publication 103, p. 187-198. (enhanced convective hydrothermal heat flow)

B. Durand and F. Behar, eds., Advances in organic geochemistry 1989, part II, molecular geochemistry: Organic Geochemistry, v. 16, p. 889-895.

Legall, F.D., C.R. Barnes, and R.W. MacQueen, 1981, Thermal maturation, burial history and hotspot development of Paleozoic strata of southern Ontario – Quebec, from conodont and acritarch colour alteration studies: Bulletin of Canadian Petroleum Geology, v. 29, p. 492-539. (proposed acritarch alteration index, AAI)

Lester, E., D. Alvarez, A.G. Borrego, B. Valentim, D. Flores, D.A. Clift, P. Rosenberg, B. Kwiecinska, R. Barranco, H.I. Petersen, M. Mastalerz, K.S. Milenkova, C. Panaitescu, M.M. Marques, A. Thompson, D. Watts, S. Hanson, G. Predeanu, M. Misz, and T. Wu, 2010, The procedure used to develop a coal char classification—Commission III Combustion Working Group of the International Committee for Coal and Organic Petrology: International Journal of Coal Geology, v. 81, p. 333-342.

S.D. Schwochow, D.K. Murray, and M.F. Fahy, eds., Coalbed methane of western North America: Denver, CO, Rocky Mountain Association of Geologists Guidebook, p. 179-190.

Li, X., S. Dai, W. Zhang, T. Li, X. Zheng, and W. Chen, 2014, Determination of As and Se in coal and coal combustion products using closed vessel microwave digestion and collision/reaction cell technology (CCT) of inductively coupled plasma mass spectrometry (ICP-MS): International Journal of Coal Geology, v. 124, p. 1-4.Li, X., S. Dai, W. Zhang, T. Li, X. Zheng, and W. Chen, 2014, Determination of As and Se in coal and coal combustion products using closed vessel microwave digestion and collision/reaction cell technology (CCT) of inductively coupled plasma mass spectrometry (ICP-MS): International Journal of Coal Geology, v. 124, p. 1-4.

B. Durand and F. Behar, eds., Advances in organic geochemistry 1989, part I, organic geochemistry in petroleum exploration: Organic Geochemistry, v. 16, p. 247-258.

Lyons, P.C., C.A. Palmer, N.H. Bostick, J.D. Fletcher, F.T. Dulong, F.W. Brown, Z.A. Brown, M.R. Krasnow, and L.A. Romankiw, 1989, Chemistry and origin of minor and trace elements in vitrinite concentrates from a rank series from the eastern United States, England, and Australia: International Journal of Coal Geology, v. 13, p. 481-527.

P.C. Lyons and E.L. Zodrow, eds., Euramerican Carboniferous paleobotany and coal geology: Review of Palaeobotany and Palynology, v. 95, p. 31-50.

Ar sanidine single-crystal plateau ages: International Journal of Coal Geology, v. 67, p. 259-266.

G. Cryc, ed., Geology and exploration of the National Petroleum Reserve in Alaska, 1974-1982: USGS Professional Paper 1399, p. 381-450.

P.M. Letourneau and P.E. Olsen, eds., The great rift valleys of Pangea in eastern North America; v. 1. Tectonics, structure, and volcanism: New York, Columbia University Press, p. 80-103.

Mardon, S.M., C.F. Eble, J.C. Hower, K. Takacs, M. Mastalerz, and R.M. Bustin, 2014, Organic petrology, geochemistry, gas content and gas composition of Middle Pennsylvanian age coal beds in the Eastern Interior (Illinois) Basin: Implications for CBM development and carbon sequestration: International Journal of Coal Geology, v. 127, p. 56-74.Mardon, S.M., C.F. Eble, J.C. Hower, K. Takacs, M. Mastalerz, and R.M. Bustin, 2014, Organic petrology, geochemistry, gas content and gas composition of Middle Pennsylvanian age coal beds in the Eastern Interior (Illinois) Basin: Implications for CBM development and carbon sequestration: International Journal of Coal Geology, v. 127, p. 56-74.

A.M. Spencer, ed., Generation, accumulation, and production of Europe's hydrocarbons II: New York, Springer-Verlag, Special Publication 2 of the European Association of Petroleum Geoscientists, p. 239-247.

L.V. Hills, C.M. Henderson, and E.W. Bamber, eds., Carboniferous and Permian of the World: Canadian Society of Petroleum Geologists Memoir 19, p. 902-909. L.V. Hills, C.M. Henderson, and E.W. Bamber, eds., Carboniferous and Permian of the World: Canadian Society of Petroleum Geologists Memoir 19, p. 902-909.

M. Mastalerz, M. Glikson, and S.D. Golding, eds., Coalbed methane: scientific, environmental and economic evaluation: Boston, Kluwer Academic Publishers, p. 33-54.

M. Grobe, J.C. Pashin, and R.L. Dodge, eds., Carbon dioxide sequestration in geological media–state of the art: AAPG Studies in Geology 59, p. 149-171.

A.C. Scott and A.J. Fleet, eds., Coal and coal-bearing strata as oil-prone source rocks?: London, The Geological Society Special Publication 77, p. 139-148.

McIntyre, M. R., R. H. Groshong, Jr., and J. C. Pashin, 2003, Structure of Cedar Cove and Peterson coalbed methane fields and correlation to gas and water production: Tuscaloosa, Alabama, University of Alabama College of Continuing Studies, 2003 International Coalbed Methane Symposium Proceedings, Paper 0312, 14 p.

Mendonça Filho, J.G., C.V. Araujo, A.G. Borrego, A. Cook, D. Flores, P. Hackley, J.C. Hower, M.L. Kern, K. Kommeren, J. Kus, M. Mastalerz, J.O. Mendonça, T.R. Menezes, J. Newman, P. Ranasinghe, I.V.A.F. Souza, I. Suarez-Ruiz, and Y. Ujiié, 2010, Effect of concentration of dispersed organic matter on optical maturity parameters: Interlaboratory results of the organic matter concentration working group of the ICCP: International Journal of Coal Geology, v. 84, p. 154-165.Mendonça Filho, J.G., C.V. Araujo, A.G. Borrego, A. Cook, D. Flores, P. Hackley, J.C. Hower, M.L. Kern, K. Kommeren, J. Kus, M. Mastalerz, J.O. Mendonça, T.R. Menezes, J. Newman, P. Ranasinghe, I.V.A.F. Souza, I. Suarez-Ruiz, and Y. Ujiié, 2010, Effect of concentration of dispersed organic matter on optical maturity parameters: Interlaboratory results of the organic matter concentration working group of the ICCP: International Journal of Coal Geology, v. 84, p. 154-165.Mendonça Filho, J.G., C.V. Araujo, A.G. Borrego, A. Cook, D. Flores, P. Hackley, J.C. Hower, M.L. Kern, K. Kommeren, J. Kus, M. Mastalerz, J.O. Mendonça, T.R. Menezes, J. Newman, P. Ranasinghe, I.V.A.F. Souza, I. Suarez-Ruiz, and Y. Ujiié, 2011, Reply to effect of concentration of organic matter on optical maturity parameters. Interlaboratory results of the organic matter concentration working group of the ICCP. Discussion by Vinay K. Sahay: International Journal of Coal Geology, v. 86, p. 289-290.

M. Grobe, J.C. Pashin, and R.L. Dodge, edcs., Carbon dioxide sequestration in geological media—State of the science: AAPG Studies in Geology 59, p. 665-688.

B. Doligez, ed., Migration of hydrocarbons in sedimentary basins: Paris, Editions Technip, Collection Colloques et Seminaires, v. 45, p. 79-112.

Mercier, T.J., 2011, Calculation of overburden above the LaClede bed of the Laney member of the Eocene Green River Formation, Green River and Washakie Basins, southwestern Wyoming: U.S. Geological Survey, Digital Data Series DDS-69-DD, chapter 4, 10 p. http://pubs.usgs.gov/dds/dds-069/dds-069-dd/REPORTS/69_DD_CH_4.pdf

Mercier, T.J., G.L. Gunther, and C.C. Skinner, 2011, The GIS project for the geologic assessment of in-place oil shale resources of the Eocene Green River Formation, Greater Green River Basin, Wyoming, Colorado, and Utah: U.S. Geological Survey, Digital Data Series DDS-69-DD, chapter 3, 5 p. http://pubs.usgs.gov/dds/dds-069/dds-069-dd/REPORTS/69_DD_CH_3.pdf

Gondwana nine, v. 2: Geological Survey of India, Ninth International Gondwana Symposium, p. 1257-1264.

T.D. Fouch, V.F. Nuccio, and T.C. Chidsey, Jr., eds., Hydrocarbon and mineral resources of the Uinta basin, Utah and Colorado: Salt Lake City, Utah Geological Association Guidebook 20, p. 257-270. (also as Utah Geological Survey Contract Report CR-92-4, 27 p.)

T. Carr, T. D’Agostino, W. Ambrose, J. Pashin, and N.C. Rosen, eds., Unconventional energy resources: making the unconventional conventional: 29 th Annual GCSSEPM Foundation Bob F. Perkins Research Conference, CD-ROM, p. 396.

K.H. Wolf and G.V. Chilingarian, eds., Diagenesis, III: New York, Elsevier, Developments in Sedimentology 47, p. 435-510. K.H. Wolf and G.V. Chilingarian, eds., Diagenesis III: Elsevier, Developments in Sedimentology 47, p. 435-510. K.H. Wolf and G.V. Chilingarian, eds., Diagenesis III: Elsevier, Developments in Sedimentology 47, p. 435-510.

P.K. Mukhopadhyay and W.G. Dow, eds., Vitrinite reflectance as a maturity parameter: applications and limitations: Washington, D.C., American Chemical Society Symposium Series 570, p. 1-24. P.K. Mukhopadhyay and W.G. Dow, eds., Vitrinite reflectance as a maturity parameter: applications and limitations: Washington, D.C., American Chemical Society Symposium Series 570, p. 1-24. P.K. Mukhopadhyay and W.G. Dow, eds., Vitrinite reflectance as a maturity parameter: applications and limitations: American Chemical Society Symposium Series 570, p. 1-24.

Mukhopadhyay, P.K., MacDonald, D.J, Calder, J. H., Hughes, J. D., and Hatcher, P.G., 1997, Relationship between methane generation/adsorption potential, micropore system, and permeability with composition and maturation – Examples from Carboniferous coals of Nova Scotia, eastern Canada: Proc. International Coalbed Methane Symposium, Tuscaloosa, Alabama, Paper 9733, p. 183-193. P.K. Mukhopadhyay, M.G. Fowler, and W.G. Dow, eds., Selected papers from the symposium on coal and terrestrial organic matter as a source rock for petroleum: Organic Geochemistry, v. 17, p. 765-783.

J.C. Pashin and R.A. Gastaldo, eds., Sequence stratigraphy, paleoclimate, and tectonics of coal-bearing strata: AAPG Studies in Geology 51, p. 29-44.

Annual GCSSEPM Foundation Bob F. Perkins Research Conference, CD-ROM, p. 353-387.

Newell, K.D., T.A. Johnson, W.M. Brown, J.P. Lange, and T.R. Carr, 2004, Geological and geochemical factors influencing the emerging coalbed gas play in the Cherokee and Forest City Basins in eastern Kansas: Kansas Geological Survey Open-File Report 2004-17. (http://www.kgs.ku.edu/PRS/publication/2004/AAPG/Coalbed/P1-02.html)

1991 New Zealand oil exploration conference proceedings, v. 2: Wellington, New Zealand, The Publicity Unit, Crown Minerals Operations Group, Energy and Resources Division, Ministry of Commerce, p. 336-350.

1994 New Zealand Petroleum Conference Proceedings: Wellington, The Publicity Unit, p. 370-384.

S.D. Schwochow, D.K. Murray, and M.F. Fahy, eds., Coalbed methane of western North America: Denver, CO, Rocky Mountain Association of Geologists Guidebook, p. 1-20.

R.F. Meyer, ed., and others, International Conference on Heavy Crude and Tar Sands: Fourth UNITAR/UNDP International Conference on Heavy Crude and Tar Sands, v. 2, p. 575-592.

Pashin, J. C., and D. E. Raymond, 2004, Glacial-eustatic control of coalbed methane reservoir distribution (Pottsville Formation; Lower Pennsylvanian) in the Black Warrior Basin of Alabama: Tuscaloosa, Alabama, University of Alabama College of Continuing Studies, 2004 International Coalbed Methane Symposium Proceedings, Paper 0413, 15 p.

Pashin, J. C., R. E. Carroll, J. R. Hatch, and M. B. Goldhaber, 1999, Interplay among cleating, maturation, and mineralization in coalbed methane reservoirs of the Black Warrior Basin: Tuscaloosa, Alabama, University of Alabama, College of Continuing Studies, 1999 International Coalbed Methane Symposium Proceedings, p. 367-375. in coal: quantifying potential of the Black Warrior coalbed methane fairway, Alabama: Final Technical Report, U.S. Department of Energy, National Technology Laboratory, contract DE-FC26-00NT40927, 254 p.

Annual GCSSEPM Foundation Bob F. Perkins Research Conference, CD-ROM, p. 329-352.

Pashin, J.C., and J.C. Sarnecki, 1990, Coal-bearing strata near Oak Grove and Brookwood coalbed-methane fields, Black Warrior Basin, Alabama: Guidebook for field trip 5, 39th Annual Meeting, Southeastern Section, Geological Society of America, 37 p. http://www.gsa.state.al.us/gsa/pubs/onlinepubs/Guidebooks/GB3-5.pdf

M. Mastalerz, M. Glikson, and S.D. Golding, eds., Coalbed methane: scientific, environmental and economic evaluation: Boston, Kluwer Academic Publishers, p. 305-327.Pashin, J.C., R.E. Carroll, R.H. Groshong, Jr., D.E. Raymond, M. McIntyre, and W.J. Payton, 2002, Geologic screening criteria for sequestration of CO2 in coal: quantifying potential of the Black Warrior coalbed methane fairway, Alabama: U.S. Department of Energy, National Energy Technology Laboratory, Annual Technical Progress Report. http://www.gsa.state.al.us/gsa/CO2PAGE/CO2page.htmPashin, J.C., R.E. Carroll, R.H. Groshong, Jr., D.E. Raymond, M. McIntyre, and W.J. Payton, 2002, Geologic screening criteria for sequestration of CO2 in coal: quantifying potential of the Black Warrior coalbed methane fairway, Alabama: U.S. Department of Energy, National Technology Laboratory, Annual Technical Progress Report. http://www.gsa.state.al.us/gsa/CO2PAGE/CO2page.htmPashin, J.C., R.E. Carroll, R.H. Groshong, Jr., D.E. Raymond, M. McIntyre, and W.J. Payton, 2003, Geologic screening criteria for sequestration of CO2 in coal: quantifying potential of the Black Warrior coalbed methane fairway, Alabama: U.S. Department of Energy, National Energy Technology Laboratory, Annual Technical Progress Report, 209 p. http://www.gsa.state.al.us/gsa/CO2PAGE/CO2page.htm

Pashin, J.C., R.H. Groshong, Jr., and R.E. Carroll, 2001, Enhanced coalbed methane recovery through sequestration of carbon dioxide: potential for a market-based environmental solution in the Black Warrior basin of Alabama: National Energy Technology Laboratory, First National Conference on Carbon Sequestration, 14 p. http://www.netl.doe.gov/publications/proceedings/01/carbon_seq/3a2.pdfPashin, J.C., R.H. Groshong, Jr., and R.E. Carroll, 2001, Enhanced coalbed methane recovery through sequestration of carbon dioxide: potential for a market-based environmental solution in the Black Warrior basin of Alabama: National Energy Technology Laboratory First National Conference on Carbon Sequestration, 14 p. http://www.netl.doe.gov/publications/proceedings/01/carbon_seq/3a2.pdfPashin, J.C., W.E. Ward II, R.B. Winston, R.V. Chandler, D.E. Bolin, K.E. Richter, W.E. Osborne, and J.C. Sarnecki, 1991, Regional analysis of the Black Creek-Cobb coalbed-methane target interval, Black Warrior basin, Alabama: Geological Survey of Alabama Bulletin 145, 127 p. (http://www.gsa.state.al.us/gsa/pubs/onlinepubs/Bulletins/B145.pdf)

Petersen, H.I., N. Sherwood, A. Mathiesen, M.B.W. Fyhn, N.T. Dau, N. Russell, J.A. Bojesen-Koefoed, and L.H. Nielsen, 2009, Application of integrated vitrinite reflectance and FAMM analyses for thermal maturity assessment of the northeastern Malay Basin, offshore Vietnam: Implications for petroleum prospectivity evaluation: marine and Petroleum Geology, v. 26, p. 319-332.Petersen, H.I., N. Sherwood, A. Mathiesen, M.B.W. Fyhn, N.T. Dau, N. Russell, J.A. Bojesen-Koefoed, and L.H. Nielsen, 2009, Application of integrated vitrinite reflectance and FAMM analyses for thermal maturity assessment of the northeastern Malay Basin, offshore Vietnam: Implications for petroleum prospectivity evaluation: marine and Petroleum Geology, v. 26, p. 319-332.

Phillips, T.L., 1980, Stratigraphic and geographic occurrences of permineralized coal-swamp plants - Upper Carboniferous of North America and Europe, in D.L. Dilcher and T.N. Taylor, eds., Biostratigraphy of fossil plants, successional and paleoecological analyses: Stroudsburg, Pennsylvania, Dowden, Hutchinson & Ross, Inc., p. 25-92.

P.K. Mukhopadhyay, M.G. Fowler, and W.G. Dow, eds., Selected papers from the symposium on coal and terrestrial organic matter as a source rock for petroleum: Organic Geochemistry, v. 17, p. 695-704.

Pickel, W., R. Wilkins, C. Buckingham, M. Faiz, J. Kurusingal, N. Russell, and N. Sherwood, 2001, Laser microscopy–FAMM: ICCP White Paper, 10 p. (rate of oxidation is related to rank; significant reduction in fluorescence intensity in one or two days) http://www.iccop.org/uploads/media/2._Pickel_et_al._-_FAMM_02.pdf

Poças Ribeiro, N., J.G. Mendonça Filho, L.V. Duarte, R.L. Silva, J.O. Mendonça, and T.F. Silva, 2013, Palynofacies and organic geochemistry of the Sinemurian carbonate deposits in the western Lusitanian Basin (Portugal): Coimbra and Água de Madeiros formations: International Journal of Coal Geology, v. 111, p. 37-52.

Pilcher, R.C., R.C. Collings, and J.S. Marshall, 2000, An overview of emerging practices and models used in coal mine methane resource estimation and reserve evaluation: Second International Methane Mitigation Conference, Novosibirsk, Russia, June 2000, 7 p. (available at Raven Ridge web site: www.ravenridge.com)Pilcher, R.C., R.C. Collings, and J.S. Marshall, 2000, An overview of emerging practices and models used in coal mine methane resource estimation and reserve evaluation: Second International Methane Mitigation Conference, Novosibirsk, Russia, June 2000, 7 p. (available at Raven Ridge web site: www.ravenridge.com)

Potter, J., A.P. Beaton, W.J. McDougall, E.M.V. Nambudiri, and L.W. Vigrass, 1991, Depositional environments of the Hart coal zone (Paleocene), Willow Bunch coalfield, southern Saskatchewan, Canada from petrographic, palynological, paleobotanical, mineral and trace element studies: International Journal of Coal Geology, v. 19, p. 253-281.

Prachiti, P.K., C. Manikyamba, P.K. Singh, V. Balaram, G. Lakshminarayana, K. Raju, M.P. Singh, M.S. Kalpana, and M. Arora, 2011, Geochemical systematic and precious metal content of the sedimentary horizons of Lower Gondwanas from the Sattupalli coal field, Godavari Valley, India: International Journal of Coal Geology, v. 88, p. 83-100.

P. Lufholm and D. Cox, eds., 2005 WTGS Fall Symposium: West Texas Geological Society, Publication No. 05-115, p. 115-122.

H.C. Wagner, L.C. Wagner, F.F.H. Wang, and F.L. Wong, eds., Petroleum resources of China and related subjects: Houston, Circum-Pacific Council for Energy and Mineral Resources, Earth Science Series, v. 10, p. 807-824.

Pusz, S., D. Alvarez, I. Camean, V. du Cann, S. Duber, A. Gómez-Borrego, W. Kalkreuth, J. Komorek, J. Kus, B. Kwiecińska, M. Marques, M. Misz, R. Morga, S. Rodrigues, Ł. Smędowski, and I. Súarez-Ruiz, 2011, Final report on application of reflectance for estimation of structural order working group (Structural WG) 2002-2010: International Committee for Coal and Organic Petrology, ICCP News, No. 52, p. 13-17.

Querol, X., X. Zhuang, O. Font, M. Izquierdo, A. Alastuey, I. Castro, B.L. van Drooge, T. Moreno, J.O. Grimalt, J. Elvira, M. Cabañas, R. Bartroli, J.C. Hower, C. Ayora, F. Plana, and A. López-Soler, 2011, Influence of soil cover on reducing the environmental impact of spontaneous coal combustion in coal waste gobs: a review and new experimental data: International Journal of Coal Geology, v. 85, p. 2-22.

R.A. Rahmani and R.M. Flores, eds., Sedimentology of coal and coal-bearing sequences: Boston, Blackwell Scientific Publications, International Association of Sedimentologists Special Publication 7, p. 3-10.

W.D. Allmon and D.J. Bottjer, eds., Evolutionary paleoecology: the ecological context of macroevolutionary change: New York, Columbia University Press, p. 235-283.

Ribeiro, J., E. Ferreira da Silva, Z. Li, C. Ward, and D. Flores, 2010, Petrographic, mineralogical and geochemical characterization of the Serrinha coal waste pile (Douro coalfield, Portugal) and the potential environmental impacts on soil, sediments and surface waters: International Journal of Coal Geology, v. 83, p. 456-466.

Reeves, S., 2001, Geologic sequestration of CO2 in deep, unmineable coalbeds: an integrated research and commercial-scale demonstration project: National Energy Technology Laboratory First National Conference on Carbon Sequestration. http://www.netl.doe.gov/publications/proceedings/01/carbon_seq/3a1.pdfReeves, S., 2001, Geologic sequestration of CO2 in deep, unmineable coalbeds: an integrated research and commercial-scale demonstration project: National Energy Technology Laboratory, First National Conference on Carbon Sequestration. http://www.netl.doe.gov/publications/proceedings/01/carbon_seq/3a1.pdf

S.D. Schwochow, D.K. Murray, and M.F. Fahy, eds., Coalbed methane of western North America: Denver, CO, Rocky Mountain Association of Geologists Guidebook, p. 209-225.

Repetski, J.E., R.T. Ryder, D.J. Weary, A.G. Harrris, and M.H. Trippi, 2008, Thermal maturity patterns (CAI and %Ro) in Upper Ordovician and Devonian rocks of the Appalachian Basin: a major revision of USGS Map I-917-E using new subsurface collections: U.S. Geological Survey Scientific Investigations Map 3006, one CD-ROM. http://pubs.usgs.gov/sim/3006/Repetski, J.E., R.T. Ryder, D.J. Weary, A.G. Harrris, and M.H. Trippi, 2008, Thermal maturity patterns (CAI and %Ro) in Upper Ordovician and Devonian rocks of the Appalachian Basin: a major revision of USGS Map I-917-E using new subsurface collections: U.S. Geological Survey Scientific Investigations Map 3006, one CD-ROM. http://pubs.usgs.gov/sim/3006/

American Institute of Mechanical Engineers Annual Meeting, p. 453-478.

S.D. Schwochow and V.F. Nuccio, eds., Coalbed methane of North America, II: Rocky Mountain Association of Geologists, p. 53-70. S.D. Schwochow and V.F. Nuccio, eds., Coalbed methane of North America, II: Rocky Mountain Association of Geologists, p. 53-70.

D.L. Gautier and others, eds., 1995 National assessment of United States oil and gas resources -- results, methodology, and supporting data: U.S. Geological Survey Digital Data Series DDS-30, release 2, CD-ROM. P.C. Lyons and B. Alpern, eds., Coal: classification, coalification, mineralogy, trace-element chemistry, and oil and gas potential: International Journal of Coal Geology, v. 13, p. 597-626.

Roberts-Ashby, T.L., S.T. Brennan, M.L. Buursink, J.A. Covault, W.H. Craddock, R.M. Drake II, M.D. Merrill, E.R. Slucher, P.D. Warwick, M.S. Blondes, M.A. Gosai, P.A. Freeman, S.M. Cahan, C.A. DeVera, and C.D. Lohr, 2012, Geologic framework for the national assessment of carbon dioxide storage resources—U.S. Gulf Coast: U.S. Geological Survey Open-File Report 2012-1024-H, 77 p.

Roberts, S.B., compiler, 2008, Geologic assessment of undiscovered, technically recoverable coalbed-gas resources in Cretaceous and Tertiary rocks, North Slope and adjacent state waters, Alaska: U.S. Geological Survey Digital Data Series DDS-69-S, CD-ROM. http://pubs.usgs.gov/dds/dds-069/dds-069-s/OPEN_FIRST/OPEN_FIRST.pdf

International symposium on use and management of coal combustion by-products (CCBs): American Coal Ash Association, o. 21-1 to 21-12.

M. Podemski, S. Dybova-Jachowicz, K. Jaworowski, J. Jureczka, and R. Wagner, eds., Proceedings of the XIII International Congress on the Carboniferous and Permian: Warsaw, Polish Geological Institute, Prace, v. 157, pt. 2, p. 387-394.

Sams, J.I., G. Veloski, B.D. Smith, B.J. Minsley, M.A. Engle, B.A. Lipinski, R. Hammack, and J.W. Zupancic, 2014, Application of near-surface geophysics as part of a hydrologic study of a subsurface drip irrigation system along the Powder River floodplain near Arvada, Wyoming: International Journal of Coal Geology, v. 126, p. 128-139.

C.B. Eckardt, J.R. Maxwell, S.R. Larter, and D.A.C. Manning, eds., Advances in organic geochemistry 1991, part I. Advances and applications in energy and the natural environment: Organic Geochemistry, v. 19, p. 77-87.

Annual GCSSEPM Foundation Bob F. Perkins Research Conference, CD-ROM, p. 303-305. B.K. Cunningham, ed., Permian and Pennsylvanian stratigraphy, Midland basin, west Texas: studies to aid hydrocarbon exploration: SEPM Permian Basin, Publication 88-28, p. 33-51.

Sechman, H., M.J. Kotarba, J. Fiszer, and M. Dzieniewicz, 2013, Distribution of methane and carbon dioxide concentrations in the near-surface zone and their genetic characterization at the abandoned "Nowa Ruda" coal mine (Lower Silesian Coal Basin, SW Poland): International Journal of Coal Geology, v. 116-117, p. 1-16.

S.D. Schwochow, D.K. Murray, and M.F. Fahy, eds., Coalbed methane of western North America: Denver, Rocky Mountain Association of Geologists, p. 93-108.

N.B. Harris and K.E. Peters, eds., Analyzing the thermal history of sedimentary basins: Methods and case studies: SEPM Special Publication 103, p. 153-165.

Self, J.G., R.T. Ryder, R.C. Johnson, M.E. Brownfield, and T.J. Mercier, 2011, Stratigraphic cross sections of the Eocene Green River Formation in the Green River Basin, southwestern Wyoming, northwestern Colorado, and northeastern Utah: U.S. Geological Survey, Digital Data Series DDS-69-DD, chapter 5, 11 p. http://pubs.usgs.gov/dds/dds-069/dds-069-dd/REPORTS/69_DD_CH_5.pdf

Silva, L.F.O., C.H. Sampaio, A. Guedes, S. Fdez-Ortiz de Vallejuelo, and J.M. Madariaga, 2012, Multianalytical approaches to the characterization of minerals associated with coals and the diagnosis of their potential risk by using combined instrumental microspectroscopic techniques and thermodynamic speciation: Fuel, v. 94, p. 52-63.

Singh, P.K., M.P. Singh, P.K. Prachiti, M.S. Kalpana, C. Manikyamba, G. Lakshminarayana, A.K. Singh, and A.S. Naik, 2012, Petrographic characteristics and carbon isotopic composition of Permian coal: Implications on depositional environment of Sattupalli coalfield, Godavari Valley, India: International Journal of Coal Geology, v. 90-91, p. 34-42.

R.A. Rahmani and R.M. Flores, eds., Sedimentology of coal and coal-bearing sequences: Boston, Blackwell Scientific Publications, International Association of Sedimentologists Special Publication 7, p. 333-347.

H.H. Schobert, K.D. Bartle, and L.J. Lynch, eds., Coal science II: Washington, D.C., American Chemical Society, Symposium Series 461, p. 182-192.

P.K. Mukhopadhyay and W.G. Dow, eds., Vitrinite reflectance as a maturity parameter: applications and limitations: Washington, D.C., American Chemical Society Symposium Series 570, p. 52-63.

Suchý, V., P. Dobeš, L. Sýkorová, V. Machovič, M. Stejskal, J. Kroufek, J. Chudoba, L. Matějovský, M. Havelcová, and P. Matysová, 2010, Oil-bearing inclusions in vein quartz and calcite and bitumens in veins: Testament to multiple phases of hydrocarbon migration in the Barrandian basin (lower Palaeozoic), Czech Republic: Marine and Petroleum Geology, v. 27, p. 285-297.

R.A. Rahmani and R.M. Flores, eds., Sedimentology of coal and coal-bearing sequences: Boston, Blackwell Scientific Publications, International Association of Sedimentologists Special Publication 7, p. 241-271.

P.K. Mukhopadhyay and W.G. Dow, eds., Vitrinite reflectance as a maturity parameter: applications and limitations: Washington, D.C., America Chemical Society, Symposium Series 570, p. 76-92.

1991 New Zealand oil exploration conference proceedings, v. 2: Wellington, The Publicity Unit, Crown Minerals Operations Group, Energy and Resources Division, Ministry of Commerce, p. 373-389.

Tedesco, S. A., 2004, Stratigraphic framework and architecture of the deltas of Pennsylvanian age in the Forest City and Cherokee Basins and their impact on coalbed methane production: Tuscaloosa, Alabama, University of Alabama, College of Continuing Studies, 2004 International Coalbed Methane Symposium Proceedings, paper 0421, 9 p.

P.K. Mukhopadhyay, M.G. Fowler, and W.G. Dow, eds., Selected papers from the symposium on coal and terrestrial organic matter as a source rock for petroleum: Organic Geochemistry, v. 17, p. 749-764.

Telle, W.R., D.A. Thompson, L.K. Lottman, and P.G. Malone, 1987, Preliminary burial - thermal history investigations of the Black Warrior basin: implications for coalbed methane and conventional hydrocarbon development: Tuscaloosa, Alabama, Proceedings of the 1987 Coalbed Methane Symposium, paper 8713, p. 37-50.

Tyler, R., A.R. Scott, W.R. Kaiser, and R.G. McMurry, 1997, The application of a coalbed methane producibility model in defining coalbed methane exploration fairways and sweet spots: examples from the San Juan, Sand Wash, and Piceance basins: Austin, Texas, Bureau of Economic Geology, Report of Investigations 244, 59 p.

S.D. Schwochow, D.K. Murray, and M.F. Fahy, eds., Coalbed methane of western North America: Denver, Rocky Mountain Association of Geologists, p. 49-59. W.B. Ayers, Jr. and W.R. Kaiser, eds., Coalbed methane in the Upper Cretaceous Fruitland Formation, San Juan basin, New Mexico and Colorado: New Mexico Bureau of Mines and Mineral Resources, Bulletin 146, p. 87-102.

R.A. Rahmani and R.M. Flores, eds., Sedimentology of coal and coal-bearing sequences: Boston, Blackwell Scientific Publications, International Association of Sedimentologists Special Publication 7, p. 349-360.

M. Mastalerz, M. Glikson, and S.D. Golding, eds., Coalbed methane: scientific, environmental and economic evaluation: Boston, Kluwer Academic Publishers, p. 67-87.

U.S. Geological Survey Oil Shale Assessment Team, 2011, Oil shale resources of the Eocene Green River Formation, Greater Green River Basin, Wyoming, Colorado, and Utah: U.S. Geological Survey, Digital Data Series DDS-69-DD, 6 chapters. http://pubs.usgs.gov/dds/dds-069/dds-069-dd/REPORTS/69_DD_CHAPTERS.pdf

Van Bergen, F., H.J.M. Pagnier, H.C.E. Schreurs, A.P.C. Paaij, C.N. Hamelinck, K.-H.A.A. Wolf, O.H. Barzandji, D. Jansen, and G.J. Ruijg, 2001, Inventory of the potential for enhanced coalbed methane production with carbon dioxide disposal in the Netherlands: Tuscaloosa, Alabama, Proceedings, International Coalbed Methane Symposium, Paper 117, p. 271-282.

Van de Wetering, N., J. Graciano Mendonça Filho, and J. Esterle, 2013, Palynofacies changes and their reflection on preservation of peat accumulation stages in the Late Permian coal measures of the Bowen Basin, Australia: A new system for coal palynofacies characterization: International Journal of Coal Geology, v. 120, p. 57-70.

B. Alpern, ed., Colloque International Petrographie de la Matiere Organique des Sediments: Paris, CNRS, p. 67-91.

W.J.J. Fermont and J.W. Weegink, eds., International symposium on organic petrology: Mededelingen Rijks Geologische Dienst, v. 45, p. 49-64.

Veld, H., N.N.M. Hanssen, W.J.J. Fermont, and H.J.M. Pagnier, 1993, Coal facies interpretations and vitrinite reflectance variations in Carboniferous coals from well Limbricht-1/1a, the Netherlands: 12th International Congress of Stratigraphy and Geology of the Carboniferous and Permian, Comptes Rendus, v. 1, p. 267-278. International Congress of Stratigraphy and Geology of the Carboniferous and Permian, Comptes Rendus, v. 1, p. 267-278.

M. Mastalerz, M. Glikson, and S.D. Golding, eds., Coalbed methane: scientific, environmental and economic evaluation: Boston, Kluwer Academic Publishers, p. 367-384.

E.D. McKee, E.J. Crosby, and others, Paleotectonic investigations of the Pennsylvanian System in the United States; Part II. Interpretive summary and special features of the Pennsylvanian System: U.S. Geological Survey Professional Paper 853, p. 33-47.

Warwick, P.D., F.C. Breland, Jr., M.E. Ratchford, and P.C. Hackley, 2004, Coal gas resource potential of Cretaceous and Paleogene coals of the Gulf of Mexico Coastal Plain, in P.D. Warwick, ed., Selected presentations on coal-bed gas in the eastern United States: U.S. Geological Survey Open-File Report 2004-1273, p. 1-25. (http://pubs.usgs.gov/of/2004/1273/2004-1273Warwick.pdf)

C. Snape, ed., Composition, geochemistry, and conversion of oil shales: Boston, Kluwer Academic Publishers, NATO ASI Series C, Mathematical and Physical Sciences, v. 455, p. 485-492.

E.D. McKee, E.J. Crosby, and others, Paleotectonic investigations of the Pennsylvanian System in the United States; Part II. Interpretive summary and special features of the Pennsylvanian System: U.S. Geological Survey Professional Paper 853, p. 73-84.

International Symposium on the Petroleum Geology and Hydrocarbon Potential of the Black Sea Area: Turkish Association of Petroleum Geologists Bulletin, v. 4, p. 133-147.

Yu, H., W. Guo, J. Cheng, and Q. Hu, 2008, Impact of experimental parameters for manometric equipment on CO2 isotherms measured: Comment on "Inter-laboratory comparison II: CO2 isotherms measured on moisture-equilibrated Argonne premium coals at 55°C and up to 15 MPa" by Goodman et al. (2007): International Journal of Coal Geology, v. 74, p. 250-258.

Petroleum Geology Conference, p. 1155-1163. Petroleum Geology Conference, p. 1155-1163.

Zhu, Z. (ed.), M. Bouchard, D. Butman, T. Hawbaker, Z. Li, J. Liu, S. Liu, C. McDonald, R. Reker, K. Sayler, B. Sleeter, T. Sohl, S. Stackpoole, A. Wein, and Z. Zhu, 2011, Baseline and projected future carbon storage and greenhouse-gas fluxes in the Great Plains region of the United States: U.S. Geological Survey Professional Paper 1787, 28 p. http://pubs.usgs.gov/pp/1787/p1787.pdf

Zhu, Z., B. Bergamaschi, R. Bernknopf, D. Clow, D. Dye, S. Faulkner, W. Forney, R. Gleason, T. Hawbaker, J. Liu, S. Liu, S. Prisley, B. Reed, M. Reeves, M. Rollins, B. Sleeter, T. Sohl, S. Stackpoole, S. Stehman, R. Striegl, and A. Wein, 2010, A method for assessing carbon stocks, carbon sequestration, and greenhouse-gas fluxes in ecosystems of the United States under present conditions and future scenarios: U.S. Geological Survey Scientific Investigations Report 2010-5233, 187 p. http://pubs.usgs.gov/sir/2010/5233/pdf/sir2010-5233.pdf

L.V. Hills, C.M. Henderson, and E.W. Bamber, eds., Carboniferous and Permian of the World: Canadian Society of Petroleum Geologists Memoir 19, p. 393-411.

American Society for Testing and Materials (ASTM), 2011, Standard test method for microscopical determination of the reflectance of vitrinite dispersed in sedimentary rocks: West Conshohocken, PA, ASTM International, Annual book of ASTM standards: Petroleum products, lubricants, and fossil fuels; Gaseous fuels; coal and coke, sec. 5, v. 5.06, D7708-11, p. 823-830, doi: 10.1520/D7708-11, http://www.astm.org/Standards/D7708.htmAmerican Society for Testing and Materials (ASTM), 2014, Standard test method for microscopical determination of the reflectance of vitrinite dispersed in sedimentary rocks: West Conshohocken, PA, ASTM International, Annual book of ASTM standards: Petroleum products, lubricants, and fossil fuels; Gaseous fuels; coal and coke, sec. 5, v. 5.06, D7708-14, p. 823-830, doi: 10.1520/D7708-11, http://www.astm.org/Standards/D7708.htm

Araujo, C.V., A.G. Borrego, B. Cardott, R.B.A. das Chagas, D. Flores, P. Gonçalves, P.C. Hackley, J.C. Hower, M.L. Kern, J. Kus, M. Mastalerz, J.G.M. Filho, J.de Olivera Mendonça, T.R. Menezes, J. Newman, I. Suarez-Ruiz, F.S. da Silva, and I.V. de Souza, 2014, Petrographic maturity parameters of a Devonian shale maturation series, Appalachian Basin, USA. ICCP Thermal Indices Working Group interlaboratory exercise: International Journal of Coal Geology, v. 130, p. 89-101.

W.R. Keefer and others, eds., Wyoming Geological Association special symposium on oil and gas and other resources of the Wind River basin, Wyoming: Casper, Wyoming Geological Association, p. 243-256.

Borrego, A.G., C.V. Araujo, A. Balke, B. Cardott, A.C. Cook, P. David, D. Flores, M. Hámor-Vidó, W. Hiltmann, W. Kalkreuth, J. Koch, C.J. Kommeren, J. Kus, B. Ligouis, M. Marques, J.G. Mendoça Filho, M. Misz, L. Oliveira, W. Pickel, K. Reimer, P. Ranasinghe, I. Suárez-Ruiz, and A. Vieth, 2006, Influence of particle and surface quality on the vitrinite reflectance of dispersed organic matter: Comparative exercise using data from the qualifying system for reflectance analysis working group of ICCP: International Journal of Coal Geology, v. 68, p. 151-170.

C.B. Eckardt, J.R. Maxwell, S.R. Larter, and D.A.C. Manning, eds., Advances in organic geochemistry 1991, part II. Advances and applications in energy and the natural environment: Organic Geochemistry, v. 19, p. 299-313.

Petroleum Geology Conference, p. 1189-1195.

Goodman, A.L., A. Busch, R.M. Bustin, L. Chikatamarla, S. Day, G.J. Duffy, J.E. Fitzgerald, K.A.M. Gasem, Y. Gensterblum, C. Hartman, C. Jing, B.M. Krooss, S. Mohammed, T. Pratt, R.L. Robinson, Jr., V. Romanov, R. Sakurovs, K. Schroeder, and C.M. White, 2007, Inter-laboratory comparison II: CO2 isotherms measured on moisture-equilibrated Argonne premium coals at 55°C and up to 15 MPa: International Journal of Coal Geology, v. 72, p. 153-164. (see Yu et al., 2008 for comment)

W.R. Keefer and others, eds., Wyoming Geological Association special symposium on oil and gas and other resources of the Wind River basin, Wyoming: Casper, Wyoming Geological Association, p. 215-242.

W.R. Keefer and others, eds., Wyoming Geological Association special symposium on oil and gas and other resources of the Wind River basin, Wyoming: Casper, Wyoming Geological Association, p. 281-294.

J.C. Pashin and R.A. Gastaldo, eds., Sequence stratigraphy, paleoclimate, and tectonics of coal-bearing strata: AAPG Studies in Geology 51, p.

Lester, E., D. Alvarez, A.G. Borrego, B. Valentim, D. Flores, D.A. Clift, P. Rosenberg, B. Kwiecinska, R. Barranco, H.I. Petersen, M. Mastalerz, K.S. Milenkova, C. Panaitescu, M.M. Marques, A. Thompson, D. Watts, S. Hanson, G. Predeanu, M. Misz, and T. Wu, 2010, The procedure used to develop a coal char classification—Commission III Combustion Working Group of the International Committee for Coal and Organic Petrology: International Journal of Coal Geology, v. 81, p. 333-342.

Mendonça Filho, J.G., C.V. Araujo, A.G. Borrego, A. Cook, D. Flores, P. Hackley, J.C. Hower, M.L. Kern, K. Kommeren, J. Kus, M. Mastalerz, J.O. Mendonça, T.R. Menezes, J. Newman, P. Ranasinghe, I.V.A.F. Souza, I. Suarez-Ruiz, and Y. Ujiié, 2010, Effect of concentration of dispersed organic matter on optical maturity parameters: Interlaboratory results of the organic matter concentration working group of the ICCP: International Journal of Coal Geology, v. 84, p. 154-165.Mendonça Filho, J.G., C.V. Araujo, A.G. Borrego, A. Cook, D. Flores, P. Hackley, J.C. Hower, M.L. Kern, K. Kommeren, J. Kus, M. Mastalerz, J.O. Mendonça, T.R. Menezes, J. Newman, P. Ranasinghe, I.V.A.F. Souza, I. Suarez-Ruiz, and Y. Ujiié, 2010, Effect of concentration of dispersed organic matter on optical maturity parameters: Interlaboratory results of the organic matter concentration working group of the ICCP: International Journal of Coal Geology, v. 84, p. 154-165.Mendonça Filho, J.G., C.V. Araujo, A.G. Borrego, A. Cook, D. Flores, P. Hackley, J.C. Hower, M.L. Kern, K. Kommeren, J. Kus, M. Mastalerz, J.O. Mendonça, T.R. Menezes, J. Newman, P. Ranasinghe, I.V.A.F. Souza, I. Suarez-Ruiz, and Y. Ujiié, 2011, Reply to effect of concentration of organic matter on optical maturity parameters. Interlaboratory results of the organic matter concentration working group of the ICCP. Discussion by Vinay K. Sahay: International Journal of Coal Geology, v. 86, p. 289-290.

Zhu, Z., B. Bergamaschi, R. Bernknopf, D. Clow, D. Dye, S. Faulkner, W. Forney, R. Gleason, T. Hawbaker, J. Liu, S. Liu, S. Prisley, B. Reed, M. Reeves, M. Rollins, B. Sleeter, T. Sohl, S. Stackpoole, S. Stehman, R. Striegl, and A. Wein, 2010, A method for assessing carbon stocks, carbon sequestration, and greenhouse-gas fluxes in ecosystems of the United States under present conditions and future scenarios: U.S. Geological Survey Scientific Investigations Report 2010-5233, 187 p. http://pubs.usgs.gov/sir/2010/5233/pdf/sir2010-5233.pdf

Borrego, A.G., C.V. Araujo, A. Balke, B. Cardott, A.C. Cook, P. David, D. Flores, M. Hámor-Vidó, W. Hiltmann, W. Kalkreuth, J. Koch, C.J. Kommeren, J. Kus, B. Ligouis, M. Marques, J.G. Mendoça Filho, M. Misz, L. Oliveira, W. Pickel, K. Reimer, P. Ranasinghe, I. Suárez-Ruiz, and A. Vieth, 2006, Influence of particle and surface quality on the vitrinite reflectance of dispersed organic matter: Comparative exercise using data from the qualifying system for reflectance analysis working group of ICCP: International Journal of Coal Geology, v. 68, p. 151-170.

Zhu, Z., B. Bergamaschi, R. Bernknopf, D. Clow, D. Dye, S. Faulkner, W. Forney, R. Gleason, T. Hawbaker, J. Liu, S. Liu, S. Prisley, B. Reed, M. Reeves, M. Rollins, B. Sleeter, T. Sohl, S. Stackpoole, S. Stehman, R. Striegl, and A. Wein, 2010, A method for assessing carbon stocks, carbon sequestration, and greenhouse-gas fluxes in ecosystems of the United States under present conditions and future scenarios: U.S. Geological Survey Scientific Investigations Report 2010-5233, 187 p. http://pubs.usgs.gov/sir/2010/5233/pdf/sir2010-5233.pdf