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Society for Ecological Restoration International SER REStoRation REadER
Series Editor: James AronsonAssociate Editor: Donald A. Falk
Editorial Board: Margaret A. Palmer, Richard J. HobbsPublished by Island Press
Highlights from The Science and Practice of Ecological Restoration
Series
� SER Restoration Reader
intRoduction
The SER Restoration Reader
It’s now or never.
Asecosystems,species,andecologicalcommunitiescontinuetosufferacceleratingdecline,damage,anddegradationasaresultofhumanactivities—andpeoplesufferfromlossofecosystemservicesandotherimpactsofclimatechange—restorationisbecomingacriticalcomponentofnatureconservation,ecosystemmanagement, and sustainable local economic development. Restoration ecologists and practitioners aretacklingdifficultproblemsaroundtheglobe,workingtorepairriversdamagedbydamsanddiversionsandhabitatdestruction,restorehealthyforestecosystemsintropicalandotherregions,andrepairgrasslands,saltmarshes,andcoralreefswhoseecologicalinteractionshavebeenseverelydisruptedbyovergrazingorhumanactivity.Moreover,inrichandpoorcountriesalike,restorationisincreasinglybeingattemptedatalllevels,fromlocal,community-basedprojectstonationalandinternationalstrategiesforsustainability.Incomingdecades,restorationasatool,communitybuilder,andphilosophywillcontinuetogainimportance.
Why “The Science and Practice of Ecological Restoration” Book Series?
Inresponsetotheurgentneedforreliableinformationandprovocativediscussiononrestorationissues,theSocietyforEcologicalRestorationInternationalandIslandPresscreatedabookseries,“TheScienceandPracticeofEcologicalRestoration.”Astheseriesnamesuggests,ouraimistocreateaninternationalforumdevotedtoadvancingrestorationscienceandpractice,aswellaspromotingtheirintegrationwiththecon-servationsciences.Theseriesofferspracticalknowledge,field-testedsolutions,inspiration,andscientificinsight from experienced practitioners and scientists that will help ecological restoration to become thepowerfulhealingtoolandintegrativesciencethattheworldsoclearlyneeds.Astheseriesgrows,wewillcontinuetoprovidethewiderangeofinformationandreportsthatpeopleworkingonrestorationprojectsneed—fromscientifictheorytopracticalhands-onadvicetonewideas.
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�SER Restoration Reader
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The SER Restoration Reader
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� SER Restoration Reader
contEntS
Ecological Restoration: Principles, Values, and Structure of an Emerging Profession 8
By Andre F. Clewell and James Aronson
Excerpt taken from “Project Roles and Contexts,” by Andre F. Clewell and James Aronson
Restoring Natural Capital: Science, Business, and Practice 20
Edited by James Aronson, Suzanne J. Milton, and James N. Blignaut
Excerpt taken from “Mainstreaming the Restoration of Natural Capital: A Conceptual and Operational Framework,” by Richard M. Cowling, Shirley M. Pierce, and Ayanda M. Sigwela
Foundations of Restoration Ecology 15
Edited by Donald A. Falk, Margaret A. Palmer, and Joy B. Zedler
Excerpt taken from “The Dynamic Nature of Ecological Systems: Multiple States and Restoration Trajectories,” by Katharine N. Suding and Katherine L. Gross
Foundation Volumes
�SER Restoration Reader
Large-Scale Ecosystem Restoration: Five Case Studies from the United States 34
Edited by Mary Doyle and Cynthia A. Drew
Excerpt taken from “Navigating the Shoals: Costs and Benefits of Platte River Ecosystem Management,” by Stephen Polasky
contEntS
Old Fields: Dynamics and Restoration of Abandoned Farmland 38
Edited by Viki A. Cramer and Richard J. Hobbs
Excerpt taken from “Old Field Vegetation Succession in the Neotropics,” by Karen D. Holl
River Futures: An Integrative Scientific Approach to River Repair 27
Edited by Gary J. Brierley and Kirstie A. Fryirs
Excerpt taken from “Social and Biophysical Connectivity of River Systems” by Mick Hillman, Gary J. Brierley, and Kirstie A. Fryirs
A Guide for Desert and Dryland Restoration: New Hope for Arid Lands 43
By David A. Bainbridge
Excerpt taken from “Desertification: Crisis and Opportunity,” by David A. Bainbridge
Restoration of Damaged Ecosystems
� SER Restoration Reader
The Tallgrass Restoration Handbook: For Prairies, Savannas, and Woodlands 59
Edited by Stephen Packard and Cornelia F. Mutel
Excerpt taken from “Orchards of Oak and a Sea of Grass,” by Virginia M. Kline
Great Basin Riparian Ecosystems: Ecology, Management, and Restoration 65
Edited by Jeanne C. Chambers and Jerry R. Miller
Excerpt taken from “Process-Based Approaches for Managing and Restoring Riparian Ecosystems,” by Jeanne C. Chambers, Jerry R. Miller, Dru Germanoski, and Dave A. Weixelman
contEntSEcological Restoration of Southwestern Ponderosa Pine Forests 70
Edited by Peter Friederici
Excerpt taken from “Ecological Restoration as Thinking Like a Forest,” by Max Oelschlaeger
Restoring the Pacific Northwest: The Art and Science of Ecological Restoration in Cascadia 50
Edited by Dean Apostol and Marcia Sinclair
Excerpt taken from “Traditional Ecology Knowledge and Restoration Practice,” by René Senos, Frank K. Lake, Nancy Turner, and Dennis Martinez
Restoration of Damaged Ecosystems
�SER Restoration Reader
Ex Situ Plant Conservation: Supporting Species Survival in the Wild 88
Edited by Edward O. Guerrant Jr., Kayri Havens, and Mike Maunder
Excerpt taken from “Population Responses to Novel Environments: Implications for Ex Situ Plant Conservation,” by Brian C. Husband and Lesley G. Campbell
Wildlife Restoration: Techniques for Habitat Analysis and Animal Monitoring 93
By Michael L. Morrison
Excerpt taken from “Populations,” by Michael L. Morrison
Assembly Rules and Restoration Ecology: Bridging the Gap between Theory and Practice 77
Edited by Vicky M. Temperton, Richard J. Hobbs, Tim Nuttle, and Stefan Halle
Excerpt taken from “Ecological Filters, Thresholds, and Gradients in Resistance to Ecosystem Reassembly,” by Richard J. Hobbs and David A. Norton
The Historical Ecology Handbook: A Restorationist’s Guide to Reference Ecosystems 83
Edited by Dave Egan and Evelyn A. Howell
Excerpt taken from “Using Dendrochronology to Reconstruct the History of Forest and Woodland Ecosystems,” by Kurt F. Kipfmueller and Thomas W. Swetnam
Valuable Tools and References
contEntS
Contents
Dedication ixPreface xiIntroduction 1
PART I. Introduction and Essential Background 5
Chapter 1.EssenceofRestoration �
Virtual Field Trip 1.RestoringDesertifiedVegetationinAustralia 1�David Tongway and John Ludwig
Chapter 2. EcologicalImpairmentandRecovery 19
Virtual Field Trip 2.RestoringCulturalLandscapesinCentralChile ��Carlos Ovalle and James Aronson
Chapter 3. CulturalEcosystems,Fire,andAlternativeStates �8
PART II. Elements of Restoration Projects 53
Chapter 4.EcologicalAttributesofRestoredEcosystems ��
Virtual Field Trip 3.RestoringWetPrairieinMississippi,USA �0George Ramseur Jr. and Andre F. Clewell
Ecological RestorationPrinciples, Values, and Structure of an Emerging Profession
AndreF.ClewellandJamesAronson
Cloth,$�0.00,ISBN9�8-1-�9���-1�8-�
Paper,$�0.00,ISBN9�8-1-�9���-1�9-�
�00�.���pages.�x10
Figures,appendix,glossary,index
Ecological REStoRation
9Chapter 10 : Project Roles and Contexts
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Chapter 5.referenceModelsandDevelopmentalTrajectories ��
Chapter 6.ProjectPlanningandEvaluation 88
PART III. Values That Restoration Addresses 97
Virtual Field Trip 4.RestoringaCommunalSavannainSouthAfrica 99James Blignaut and Rudi van Aarde
Chapter 7.ValuesandEcologicalRestoration 10�
Virtual Field Trip 5.RestoringForestsandPeople’sWell-BeinginSouthernIndia 11�Narayanan Krishnakumar and T. S. Srinivasa Murthy
Chapter 8.AFour-QuadrantModelforHolisticEcologicalRestoration 11�
PART IV. Structure of an Emerging Profession 123
Virtual Field Trip 6.RestoringDrainedPeatlandsforSustainableUseinGermany 1��Achim Schäfer and Wendelin Wichtmann
Chapter 9.RelationshipofRestorationtoRelatedFields 1�0
Virtual Field Trip 7.RestoringDoglegBranchinFlorida,USA 1�1Andre F. Clewell
Chapter 10.ProjectRolesandContexts 1��
Virtual Field Trip 8.SettingUpaLong-TermRestorationEcologyResearchSiteinSouthernFrance 1�8James Aronson and Edouard Le Floc’h
Chapter 11.RecognizingtheProfessionandtheProfessional 1��
PART V. Holistic Ecological Restoration 167
Chapter 12.TheConceptofHolisticEcologicalRestoration:ASynthesis 1�9
Appendix:GuidelinesforDevelopingandManagingEcologicalRestorationProjects 1��Andre F. Clewell, John Rieger, and John Munro
Glossary 191
References 199
AbouttheAuthorsandCollaborators �09
Index �11
10 Ecological Restoration
SER Restoration Reader
From chapter 10, “Project Roles and Contexts”
In this chapter we describe ecological restorationprojects from the perspective of their organizationandstructure.Webeginwith therolesvariousper-sonnel play in the development and execution of aproject.Thenweprovideanoutlineofprojectcon-textsorcircumstancesinwhichprojectsareconduct-ed.Thevariouscontextshavedifferentstrengthsandweaknesses,whichweidentify.Wenotehowprojectstendtochangeovertimefrombeingexploratoryandexperimentalatfirsttorefinedandstandardizedlat-er.Thisinformationwillletstudentsandentry-levelpersonnelknowwhattheycanexpectandwheretheymaywanttoconcentratetheirtalentsastheircareersbegin.Asthechapterprogresses,wewillpresentma-terialofbroaderinterest.
Project Roles
Whosponsorsrestorationprojects?Whoadministersthem?Whomakesdecisions,andwhocarriesthemout? Every ecological restoration project requirespersonneltofulfillcertainroles,beginningwiththeprojectsponsorandcontinuingwiththerestorationpractitioner,projectdirector,restorationplanner,andprojectmanager.Insmalloruncomplicatedprojects,the same person may assume two or more of theseroles.Organizationchartsmay identifyprojectper-sonnelwithothertitles;however,eachoftheserolesisfilledbysomeone,regardlessofhisorhertitle.Everyproject has at least one practitioner and sometimes
many.Largersponsoringorganizationsmayaddoth-erlevelstotheorganizationaltableforaproject,suchasanadministratortowhomtheprojectmanagerre-ports.Projectorganizationbecomesevenmorecom-plexascontractorsandsubcontractorsareincluded,withtheirownhierarchiesofpersonnelanddepart-ments with project responsibility. We ignore thesecomplexities and describe the basic project roles inthissection.
Sponsor
Theorganizationorentitythatundertakesanecolog-icalrestorationprojectandassumestheresponsibil-ity for itsaccomplishment is its sponsor.Asponsormaybeagovernmentagencyora transnationalor-ganization; a for-profit firm or corporation; a non-government organization (NGO); a philanthropicfoundation;aschool,university,orresearchinstitute;a public museum, arboretum, or zoological park; aprofessional association; a branch of the military; amonasteryorotherreligiousorder;atribalcouncilofelders;awomen’sself-helpgroup,whicharebecomingincreasinglycommoninIndiaandLatinAmerica;an-otherkindofcommunity-basedorganization(CBO);oranindividuallandownerormanager.Thesponsorapprovestherestorationproject,providesorattractsfunding, assembles personnel who will accomplishtheproject,providesanadministrativestructure,andprovidesoversighttoensureitssatisfactorycomple-tion.Theprojectmaybeaccomplishedinhouseus-ing the sponsor’s own employees or members, orsomeorallof theworkcanbedelegatedtooutsideindividuals,consultingfirms,orotherorganizationsundercontract,purchaseorder,orsomeotheragree-menttoprovideservices.Laborcanbeprovidedbypaid personnel or by volunteers who work withoutmonetary compensation. To a restoration practitio-nerwhoiscontracted,thesponsorisusuallyknownsimplyastheclient.
Practitioner
Arestorationpractitioner issomeonewhopersonallyconductsor supervises ecological restoration in thefieldatprojectsites.Specifically,practitionersengagein project implementation and aftercare. In manyprojects,practitionersadditionallyinventoryaproj-
About This Excerpt
The field of ecological restoration is a rapidlygrowing discipline that encompasses a widerange of activities and brings together prac-titioners and theoreticians from a variety ofbackgrounds and perspectives. In Ecological Restoration,AndreClewellandJamesAronsonofferalong-awaitedguidetothepracticeofthisambitious and promising new discipline. Thisexcerptexaminestheroles,contexts,andinsti-tutionalstructureofprojectwork.
11Chapter 10 : Project Roles and Contexts
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ectsitebeforetheinitiationofrestorationactivities,select and inventory reference sites, prepare projectplans, conduct or supervise site preparation activi-ties, and monitor project sites that have undergonerestoration.Inotherprojects,sponsorsdelegatetheseresponsibilities to others. A practitioner can be anemployeeofanorganizationthatisconductingeco-logical restoration, or a consultant, contractor, sub-contractor,orvolunteerwhoisengagedbythatorga-nization.Apractitionermayalsobetheownerofthepropertythatisundergoingrestoration.Arestorationprojectmaybeaccomplishedbyasinglepractitioner,or two or more practitioners who work collectivelyonallaspectsorseparatelyondifferentaspectsofaproject. The chief practitioner, if one is appointed,supervisesotherpractitionersandisresponsiblefortheoverallconductofon-siterestorationactivities.Apractitioner may assume broad responsibilities andauthorityforconductingrestorationormayserveasatechnicianwhoperformsspecifictasksassignedbyasupervisor.
Project Director
Theprojectdirectoristhepersonwhohasacompre-hensivevisionfortheproject,includingitstechnical,social, economic, strategic, political, historical, andotherculturalaspectsand implications.Theprojectdirector is superior in rank to the project managerandisresponsiblefortheoveralltechnicaldirectionand leadership of a project. The project director iscritically involved with the conception of a projectand the development of project plans. The projectdirectorformulatesorapprovesprojectgoalsandob-jectivesandselectsorapprovesreferencemodelsandstrategiesforaccomplishingrestoration.Theprojectdirectorreceivesbriefingsfromtheprojectmanagerand evaluates project monitoring reports and othertechnical documents that may be produced. Theproject director ensures that executive officers, ac-countants,legalcounsel,andotheradministrativeof-ficersofthesponsoringorganizationunderstandtheprojectandcarryouttheirrespectiveresponsibilities.Theprojectdirectorrepresentstheprojectbeforetheboardofdirectors,philanthropicfoundations,publicofficials,stakeholders,andthegeneralpublicordel-egatesthesedutiestoothers.
Restoration Planner
Therestorationplanner(oraplanningstaff)preparesproject plans, including maps, drawings, and writ-ten instructions as needed. Ideally, the practitionercontributes substantially to the planning process orevenservesastheplanner,ascommonlyhappensonsmallerprojectsthatdonotentailmanygovernmentpermitsoroutsidecontractors.Thedegreeofdetailin project plans may vary widely between projects,dependingonprojectsizeandcomplexityandontherequirementsof thesponsoringorganization.Muchdetailmayberequiredbygovernmentagencieswhoseapproval is needed before project implementation.Projectplanstypicallyareappendedtopermitsandarecarriedoutasapermitcondition.Detailedplansarealsousefulforpreparingcontractstipulationsthataretobefollowedbythefirmthatprovidespractitio-nerservicestothesponsoringorganization.Penaltiesthataffectmonetarycompensationareprescribedifcontractorsfailtocomplywithcontractstipulations.Insuchinstances,theplanningfunctionmayincludelegalaswellastechnicalcapacity.
Project Manager
Inmostprojects,restorationpractitionersaresuper-visedandreporttoasuperiorwhoiseithertheproj-ect manager or someone who fulfills that role. Theproject manager is responsible for ensuring that agiven restoration project is conducted satisfactorilyonbehalfof thesponsoringorganization.Theproj-ectmanageradministersday-to-dayoperationssuchas scheduling personnel, arranging for deliveries ofplantingstocksandequipment,ensuringadherencetocontractstipulations,andapprovingexpenditures.Sometimes thepractitionerdoesmostof thiswork,and the project manager ensures that it is accom-plished.Anotherfirmororganizationthathasbeenengaged to provide restoration services under con-tractsometimesappointitsownprojectmanager.Insuchinstances,thetwoprojectmanagersmaycom-municate with each other, and practitioners receivedirections primarily from the project manager intheirownfirm.Satisfactory restoration projects require that thepractitionerandtheprojectmanagerremaininclosecommunication,moresothaninconstructionproj-
1� Ecological Restoration
SER Restoration Reader
ects,wheretaskswithmorepredictableoutcomesareconducted.Thesuccessofmanyrestorationprojectsdepends on manipulating living organisms of dif-ferentkinds,andthechancesforsurprisearemuchgreater.Thepractitionermustreacttounanticipatedsituations to ensure the success of the project. Theproject manager is obliged to ensure adherence toschedules,budgets,andcontractstipulations,whichmay not allow for contingencies. In such instances,the practitioners should educate project managersand provide succinct information and persuasivelogicthatthemanagerscanuseeffectivelywhenin-teractingwithpeopleathigheradministrativelevels.Wecannotoverstatetheimportanceofrespectfulandcordial relations between practitioner and projectmanager,particularly inecological restorationproj-ectsoflongduration.
Project Contexts
Thecontextofarestorationprojectconsistsofthecir-cumstancesunderwhichitisconducted.Theadmin-istrativestructureofaprojectisthemostimportantaspectofcontext.Otherfactorscontributingtoitaretheavailabilityoffunding,labor,equipment,andma-terialssuchasplantingstocks.Projectsiteaccessibil-ityandseasonalconstraints(e.g.,inclementweather)canalsoinfluencethecontext,ascanregulatoryandlegalconstraints.Weemphasizeadministrativestruc-tureintheensuingdiscussion.Thewaysinwhichdifferentprojectsareadministeredvary widely. Project administration determines thedegreeofresponsibilitythattherestorationpractitio-ner isgiven, theamountofauthority that theprac-titionerisallotted,andultimatelytheflexibilitythattherestorationpractitionercanapplytosolveprob-lemsthatarise.TheNorthBranchPrairieprojectandthe Dogleg Branch project illustrate two extremesin project administration and context. The NorthBranchPrairieprojectwasdescribedinMiracle Un-der the Oaks byWilliamStevens(199�)andcritiquedbyPeterFriederici(�00�).TheDoglegBranchproj-ectisdescribedinVirtualFieldTrip�.The North Branch Prairie project was initiated in19��byStevePackardandasmallgroupofenviron-mental activists near Chicago, Illinois. Packard ap-proachedapublicofficialintheCookCountyForestPreserveDistrictandaskedwhethertheycouldvol-
unteertocleanuptrash,cutsomebrush,scattersomeseeds,andgenerallyrefurbishdegradedprairiesthatthedistrictowned.Districtpersonnelhadwantedtobeginsuchworkthemselvesbutwerehamperedbyalackoffunds,andtheyacceptedPackard’soffer.Theworkbeganandsoonattractedothervolunteers.TheideaofrestoringChicago’sformerecosystemsspreadlikeaprairiewildfire.Soon,hundredsofcitizenswerespendingtheirfreetimeworkingalongsidePackard,essentiallywithoutplansoradministrativestructure.By 199�, more than �,000 volunteers had restoredmorethan�,�00hectaresofdegradedprairieandas-sociatedoaksavannainanamazingdisplayofaltru-ism.Compare the North Branch Prairie story to that ofthe restoration of forested wetlands in the headwa-tersofDoglegBranchonsurface-minedandphysi-callyreclaimedlandinFlorida,describedintheVir-tualFieldTrip�.Thatprojectrequiredtwoyearsofworksimplytoobtaintherequiredgovernmentper-mits. Permits were eventually issued after the min-ing company had conducted a four-year pilot proj-ecttodemonstratethatnativetreescouldbegrownandatwo-yearecologicalinventoryoflocalforestedwetlandsthatservedasreferencesites(Clewelletal.198�).Professionalswhowereinvolvedintheprojectincludedminingengineers,mineplanners,environ-mentalconsultants,nativenurseries,projectmanag-ers,heavyequipmentcontractors,attorneys, topof-ficials in state government, and large support staffsthatproducedmanyreamsofpaperwork.Theprojectwasaverycostlyandwell-orchestratedproductioninwhichtheactualrestorationworkattheprojectsireseemedlikeanafterthought.ThecontrastbetweentheNorthBranchPrairieandDogleg Branch projects could scarcely have beengreater. They demonstrate extreme examples of thecontextsinwhichrestorationpractitionersfindthem-selvesworking.Thereisnopreferredwaytoorganize,plan, and implement restoration projects. The par-ticularcircumstancesforaprojectdetermineitscon-text. The underlying difference between the NorthBranchPrairieandDoglegBranchprojectswasthattheformerwasanelectiveproject,whereasthelatterprojectrequiredpriorgovernmentapproval.Let’s look at these two projects from the perspec-tiveoftherestorationpractitioner.AtNorthBranch
1�Chapter 10 : Project Roles and Contexts
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Prairie, almost everyone involved was a restorationpractitioner.StevePackardassumedtheroleofproj-ectdirector,andheandseveralothersassumedthecollectiveroleofprojectmanageraswell.TheCookCounty Forest Preserve District was nominally thesponsor,anditspersonnelprovidedskeletaladminis-tration.Packardreferredtoexistingecologicallitera-ture,ageneralknowledgeofthefewremnantpatchesofprairieandoaksavanna,andthespecieslistofanearlynaturalistasreferencesandasanindicationofhistoric trajectory. They essentially developed proj-ect plans as they worked on site. Their administra-tivemodewascollegial.Inotherwords,Packardandtheotherpractitionerswhoworkedmostcloselywithhimmadeprojectdecisionsbyconsensus.Theyas-sumed almost total responsibility for all restorationwork. The Cook County Forest Preserve Districtretained basic authority for the project because theprojecttookplaceonlandsundertheirjurisdiction.Districtpersonnelestablishedtheboundsforprojectwork to ensure that it was legal and complied withthedistrict’soverallmission.Otherwise,Packardandhis cadre assumed authority for project operations.Inthiscontext,thepractitionersenjoyedbroadflex-ibilitytoconducttheprojectastheysawfit(Packard1988,199�).The North Branch Prairie project was a grassroots,bottom-upendeavorthatwasnotmandatedbyapub-licagency.Instead,theCookCountyForestPreserveDistrictbenefited fromthebroadpublic supportofhundredsofcitizenswhovolunteeredtheirfreetimeas restoration practitioners. This was a marvelousexampleofpeopletakingcollectiveresponsibilityfortheirownconcerns inamanner thatnicely reflectsthe four-quadrant model of ecological restoration(see Chapter 8). Ecological values were fulfilled di-rectly by the restoration. The motivation for manyvolunteers was the fulfillment of individual valuessuchasreconnectingwithnatureandrespondingtoenvironmentalcrises,asdescribedinChapter�.Pub-liccelebrationsattherestoredprairieweredescribedbyHolland(199�)andareamongtheevidenceofthefulfillment of cultural values. The restored prairiesandoaksavannasrepresentnaturalcapitalandpro-videsocioeconomicservices.Ingreatcontrast,theDoglegBranchprojectwascon-ductedbyonlyafewrestorationpractitioners,prin-cipallyAndreClewellandseveralcolleagues.Because
of thesafetyand liability issues,novolunteerswereinvitedorallowedontheproperty.Theminingcom-pany was the sponsor, and its employees assumedthe other roles of project administration, director,andprojectmanager.Mostwereengineers.Detailedprojectplanswerepreparedbythecompany,whichincorporated specific conditions that were requiredbypermitfromtheStateofFlorida.Theseconditions,inturn,werebasedinpartonarestorationplanwrit-tenbyClewellthatidentifiedrestorationgoals,objec-tives,performancestandards,andthereferencemod-el. The latter was embodied in the aforementioneddocument that described historic conditions andcontemporarychangesinthehistorictrajectorythatwereattributabletolanduse(mainlyfiresuppressionthatallowedbroadleavedforesttypicalofrivervalleystoreplaceuplandpinesavannas).Muchoftheproj-ectworkwasconductedbyearthmovingfirms,treeplantingcrews,andothersubcontractorshiredbytheminingcompany.Theroleoftherestorationpracti-tionerwaslargelytoserveasaliaisonwithforemenofsubcontractingcompanies,totestnewrestorationmethodssuchasinterplantingundergrowthspecies,to monitor forest development, and to suggest im-provementstotherestorationprocessforapprovalbyminemanagers.TheDoglegBranchprojectwasrequiredbytheStateofFlorida(primarily;othergovernmententitieswerealso involved) and was administered from the topdownbytheminingcompany.Stakeholder involve-ment was limited to formal hearings that were re-quiredby law, inwhichcitizenscouldexpress theirinterests.Commentswerelargelylimitedtolocalres-identswhowereconcernedaboutminingoperationsnear their properties and environmental organiza-tionsthatweregenerallyopposedtosurfacemining.Theintentoftheprojectwastorepairenvironmen-taldamagethatwasanunavoidableresultofminingratherthantocausenetecologicalimprovements.Nofulfillment of the personal, cultural, and socioeco-nomic values described in Chapter � was intended.Inotherwords,thiswasacompensatorymitigationproject.After thisandotherrestorationprojectsonmine land were complete, the land was donated totheStateofFloridaandbecametheAlafiaRiverStatePark, which was a cultural improvement. However,negotiationsforthedonationofthelandwereiniti-atedafterDoglegBranchwasnearlyrestored,andthe
1� Ecological Restoration
SER Restoration Reader
restorationsitehasnotyetbeenopenedforpublicac-cess.DoglegBranchrestorationisnarrowlyfocusedas a flatland project in terms of the four-quadrantmodelinChapter8inthatitsatisfiesecologicalandsocioeconomic elements that are expressed in statepolicy that presumably represents the sentiment oftheelectorate.However, a number of restoration techniques weretested during the course of Dogleg Branch restora-tion,someforthefirsttime.Theresultsweremadeavailable for use by restoration practitioners whotouredthesite,attendedconferenceswheretheproj-ectwasdescribed,andreadpublicdescriptions(e.g.,ClewellandLea1990;Clewelletal.�000).Evenmoreimportantly, the Dogleg Branch restoration project,and several others that were initiated at the time(Clewell 1999), demonstrated that complex forestandstreamrestorationcouldbeconductedon landthathadbeenliterallyturnedupsidedownbymin-ing. In this regard, the Dogleg Branch restorationprojectchanged theperceptionsofpeoplewhohadnotpreviouslyrealizedthepotentialofecologicalres-toration.Thisandsimilar restorationworkhashadthesalubriouseffectofhasteningtheeraofecologicalrestorationandprovidingjobsformanypractitionersinFloridaandelsewhere.However,ithasalsogivenregulatedinterestsarationaleforconvincinggovern-mentagenciestoissuepermitsfordevelopmentthatwill cause environmental damage with the promisethat the damage will be compensated by ecologicalrestoration as a form of mitigation. This strategycouldbejustifiedifregulatedinterestswererequiredtosuccessfullyrestoremorethantheydamaged,butthiseventualityawaitsdocumentationasanormallyoccurringoutcome.Wehopethatrestorationpracti-tionerswillbemorethanbattlefieldphysiciansintheenvironmentalwars.
Excerpted from Ecological Restoration by Andre F. Clewell and James Aronson. Copyright © 2007 by Island Press. Excerpted by permission of Island Press. All rights reserved. No part of this excerpt may be reproduced or reprinted without permission in writing from the publisher. Island Press grants permission to forward this unaltered electronic document to friends, colleagues, and other interested parties.
foundationS of REStoRation Ecology
Foundations of Restoration Ecology
EditedbyDonaldA.Falk,MargaretA.Palmer,andJoyB.Zedler
ForewordbyRichardJ.Hobbs
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Paper,$�9.9�,ISBN1-�9���-01�-�
�00�.�8�pages.�x10
Tables,figures,index
Contents
Foreword ixRichard J. Hobbs
Acknowledgments xi
Chapter 1.EcologicalTheoryandRestorationEcology 1Margaret A. Palmer, Donald A. Falk, and Joy B. Zedler
PART I. Ecological Theory and the Restoration of Populations and Communities 11
Chapter 2.PopulationandEcologicalGeneticsinRestorationEcology 1�Donald A. Falk, Christopher M. Richards, Arlee M. Montalvo, and Eric E. Knapp
Chapter 3.EcophysiologicalConstraintsonPlantResponsesinaRestorationSetting ��James R. Ehleringer and Darren R. Sandquist
Chapter 4.ImplicationsofPopulationDynamicandMetapopulationTheoryforRestoration �9Joyce Maschinski
Chapter 5.RestoringEcologicalCommunities:FromTheorytoPractice 88Holly L. Menninger and Margaret A. Palmer
Chapter 6.EvolutionaryRestorationEcology 11�Craig A. Stockwell, Michael T. Kinnison, and Andrew P. Hendry
1� Foundations of Restoration Ecology
SER Restoration Reader
PART II. Restoring Ecological Function 139
Chapter 7.TopographicHeterogeneityTheoryandEcologicalRestoration 1��Daniel Larkin, Gabrielle Vivian-Smith, and Joy B. Zedler
Chapter 8.Food-WebApproachesinRestorationEcology 1��M. Jake Vander Zanden, Julian D. Olden, and Claudio Gratton
Chapter 9.TheDynamicNatureofEcologicalSystems:MultipleStatesandRestorationTrajectories 190Katharine N. Suding and Katherine L. Gross
Chapter 10.BiodiversityandEcosystemFunctioninginRestoredEcosystems:ExtractingPrinciplesforaSyntheticPerspective �10Shahid Naeem
Chapter 11.AModelingFrameworkforRestorationEcology ��8Dean L. Urban
PART III. Restoration Ecology in Context 257
Chapter 12.UsingEcologicalTheorytoManageorRestoreEcosystemsAffectedbyInvasivePlantSpecies ��0Carla M. D’Antonio and Jeanne C. Chambers
Chapter 13.StatisticalIssuesandStudyDesigninEcologicalRestorations:LessonsLearnedfromMarineReserves �80Craig W. Osenberg, Benjamin M. Bolker, Jada-Simone S. White, Colette M. St. Mary, and Jeffrey S. Shima
Chapter 14.EcologicalRestorationfromaMacroscopicPerspective �0�Brian A. Maurer
Chapter 15.ClimateChangeandPaleoecology:NewContextsforRestorationEcology �1�Constance I. Millar and Linda B. Brubaker
Chapter 16. IntegratingRestorationEcologyandEcologicalTheory:ASynthesis ��1Donald A. Falk, Margaret A. Palmer, and Joy B. Zedler
AbouttheEditors ���
AbouttheContributors ��9
Index ���
1�Chapter 9 : The Dynamic Nature of Ecological Systems
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About This Excerpt
“Restorationisthekeystonestrategyforconserv-ingbiodiversity,andecologyhasmatured intoa central discipline of the biological sciences.This important work shows that their synergyoffersnewhopeforthefutureoflifeonEarth.”—EdwardO.Wilson,UniversityResearchPro-fessorEmeritus,HarvardUniversity
Linking theoretical models of ecosystem andcommunitychangewithrestorationecologyhasthepotentialtoadvanceboththepracticeofres-torationandourunderstandingofthedynam-ics of degraded systems. In the chapter fromwhichthisexcerpt isdrawn,KatharineSudingandKatherineGrossconsiderecological theo-ries that address questions about how systemschangeandmayreducetheriskofunpredictedchangeinrestorationprojects.
From chapter 9, “The Dynamic Nature of Ecological Systems: Multiple States and Restoration Trajectories,” by Katharine N. Suding and Katherine L. Gross
One feature of ecological systems is that they areever-changing and dynamic. As ancient Greek phi-losopherHeraclitusclaimed,“Youcanneverstepinthesamerivertwice.”Moreover,ratesanddirectionsofchangeinsystemsareshapedincreasinglybyhu-manactivities.Theseeffectscanbeintentionalortheconsequencesofengineeringofthesystemsandsur-rounding landscapes to provide specific services tohumans.Thedynamicsofanecologicalsystem,par-ticularlyofasystemslatedforrestoration,isafunc-tion of many factors, some deterministic and somestochastic, working at several temporal and spatialscales.Inconsideringhowsystemschangeinrestoration,weaddressseveralquestions:
Whattypesof trajectoriescharacterizetherecov-eryofdegradedecosystems?Isthepathwaytore-coverysimilartothepathwaytodegradation?
1.
Canwepredicttheendstatesofrestorationpath-ways?Aretheysimilartostatespriortodegrada-tion?How will dynamics that occur on very differentscales of space and time relate to one another?Whatshouldbethescaleoffocus?Howmuchinherentvariabilitydoesanecologicalsystemrequireforadequaterecoveryandadaptivecapacityforchangeinthefuture?
In thischapter,weconsiderecological theories thathelpaddressthesequestionsandmayreducetheriskof unpredicted or undesired change in restorationprojects.Whiletheorycanhelpguiderestorationef-forts,itdoesnotprovidesimpleoruniversalanswersforthechallengesthatconfrontrestoration.Restora-tioneffortsthatdocumentspeciesturnoverandenvi-ronmentalattributesovertimecanhelptestandrefineecological theory related to community dynamics.Linksbetweenrestorationandcommunitydynamicsadvanceboththepracticeofrestorationandtheoriesofecologicaldynamics.Wesurveytheprogressandthefurtherpotentialofthisconnection.
Major Theories and Connection to Restoration
Over the last one hundred years, extensive workhas documented how communities and ecosystemschangeinresponsetodisturbance.Despitetheexten-sivedocumentationofpatterns(Figure9.1),ageneralconceptual framework concerning the controls onspecies turnoverandecosystemdevelopment isstilldebated. Several contrasting views concerning themechanismsandpredictivenatureofthesedynamicspersisttoday.Inthischapter,wewillfocusonthreeviews: equilibrium, multiple equilibrium, and non-equilibrium.Wediscusseachoftheseandrelatethemtotheconceptoffastandslowprocesses(sensuRin-aldiandScheffer�000)asawaytoevaluatemecha-nismsofrecovery.
Single Equilibrium Endpoint
Equilibriumsystemsareassumed to return to theirpredisturbance state or trajectory following distur-bance (Table 9.1). This theory predicts a classicalsuccessionaltrajectory:steady,directionalchangeincompositiontoasingleequilibriumpoint(Clements
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18 Foundations of Restoration Ecology
SER Restoration Reader
191�;Odum19�9)(Figure9.�a).Recoveryinanequi-libriumframeworkisapredictableconsequenceofin-teractionsamongspecieswithdifferentlifehistoriesandthedevelopmentofecosystemfunctions.Stronginternalregulationoccursthroughnegativefeedbackmechanisms, including competition and herbivore/predator interactions, as well as climate-ecosystemcouplings and life-history tradeoffs. Many of thesemechanisms are considered aspects of communityassemblyrules(WeiherandKeddy1999;BoothandSwanton�00�),althoughassemblyrulesdonotnec-essarilyassumesingleequilibriumdynamics.
Insomecases,communitydevelopmentcanproceed“spontaneously,” with little or no intervention, toreachdesirabletargetstates(Prachetal.�001;Khateretal.�00�;NovakandPrach�00�).MitschandWil-son (199�)argue thatnaturehas a “self-design”ca-pacityasspeciesassemblethemselves.However,theextent to which this capacity can be expressed in arecoverywilldependonhowdegradedandisolatedithasbecomepriortorestorationefforts(BakkerandBerendse�001).Somerestorationeffortsaredesignedtoacceleratenaturalsuccessionsothattheecosystemdevelopsalongthesametrajectoryasitwouldintheabsenceofinterventionbutreachesthegoalendpointsooner. For instance, restoring a severely degradedriverbacktoitsmorenaturalflowregimeviadamre-movalcanenhancerecoveryofthesurroundingplantcommunities(Roodetal.�00�;LytleandPoff�00�).Similarly,prescribedburningofdegradedgrasslandscanpromoterestorationofnativeplantassemblages,particularlyifthefiremanagementregimeisappliedaccordingtohistoricalpatterns(Baeretal.�00�;Co-pelandetal.�00�).Thus, restorationofsomecom-munities can take a single equilibrium approach tospurrecoveryalongasuccessionaltrajectory.
Excerpted from Foundations of Restoration Ecology edited by Donald A. Falk, Margaret Palmer, and Joy B. Zedler. Copyright © 2006 by Island Press. Excerpted by permission of Island Press. All rights reserved. No part of this excerpt may be reproduced or reprinted without permis-sion in writing from the publisher. Island Press grants permission to forward this unaltered electronic document to friends, colleagues, and other interested parties.
Figure 9.1: Dynamics of species replacement have been predicted to take many different forms. Four general patterns of trajectories, each with two starting points (assemblages A and B) are shown here: (1) Convergent trajectories where initial variability eventually converges to similar species composition, often termed the (D) equilibrium “climax” community. (2) Initially divergent trajectories that eventually converge to one equilibrium state. (3) Divergent trajectories that never converge and never reach a permanent state. (4) Divergent trajectories that go to two different stable states (C and D) and, in the case of C, experience an abrupt shift to a third state.
19Chapter 9 : The Dynamic Nature of Ecological Systems
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Table 9.1: General theories that attempt to predict how the composition and function of systems change over time and/or behave following a disturbance.
Equilibrium Multiple Equilibrium Non-equilibrium
Assumptions Climax equilibrium, unidirectional, continuous
Equilibrium, multidirectional, discontinuous
Persistent non-equilibrium, nondirec-tional, discontinuous
Permanent states One (climax) More than one None
Trajectories Convergent Regime shifts, collapses Divergent, arrested, cyclic
PredictabilityHigh; based on species attributes
Moderate; possible but difficult Low; chance and legacies important
Important factorsSpecies interactions, ecosystem development
Initial conditions, positive feedbacks, landscape position
Chance dispersal, stochastic events
Figure 9.2: Examples of dynamics predicted by single equilibrium, per-sistent non-equilibrium, and multiple equilibrium theories (A–C). For each, the left frame shows predicted combinations of “fast” and “slow” variables; arrows indicate direction of change if not at equilibrium. The right frame shows a stylized example from the ecological literature that is consistent with the ecological predictions. In A, changes in the slow and fast variables are linear and unidirectional. Insect species diversity increase linearly in a Minnesota old-field with years since abandon-ment. Increases in aboveground productivity with time is likely the slow variable that drives the change in insect diversity (Siemann et al. 1999). In B, a persistent non-equilibrium exists with no predictable trajectory. Total stem length of cordgrass (Spartina foliosa) shows high interannual variability and no directional trends in time since restora-tion in San Diego Bay, CA (Zedler and Callaway 1999). In C, at a single level of the slow variable there are two possible equilibrial states. Ex-amples of a pattern predicted by this dynamic, shown in Figure 9.1(4), are strong threshold effects as the slow variable changes. For instance, in a fragmented Eucalyptus forest in Australia, the probability that a gecko species (Oedura retiulcata) persists decreases dramatically if the forest remnant contains less than 400 trees (Sarre et al. 1995).
REStoRing natuRal capital
Restoring Natural CapitalScience, Business, and Practice
EditedbyJamesAronson,SuzanneJ.Milton,andJamesN.Blignaut
ForewordbyPeterRaven
Cloth,$90.00,ISBN1-�9���-0��-�
Paper,$��.00,ISBN1-�9���-0��-0
�00�.�00pages.�x10
Tables,figures,index
Contents
Foreword xiPeter Raven
Preface xiii James Aronson, Suzanne J. Milton, and James N. Blignaut
PART I. Restoring Natural Capital: The Conceptual Landscape 1
IntroductionJames N. Blignaut, James Aronson, and Suzanne J. Milton
Chapter 1.RestoringNaturalCapital:DefinitionandRationale �James Aronson, Suzanne J. Milton, and James N. Blignaut
Chapter 2.RestoringNaturalCapital:AReflectiononEthics 9James N. Blignaut, James Aronson, Paddy Woodworth, Sean Archer, Narayan Desai, and Andre F. Clewell
Chapter 3.RestoringNaturalCapital:AnEcologicalEconomicsAssessment 1�Joshua Farley and Erica J. Brown Gaddis
Chapter 4.RestoringNaturalCapital:AMainstreamEconomicPerspective �8Eugenio Figueroa B.
�1Chapter 34 : Mainstreaming the Restoration of Natural Capital
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Chapter 5.AssessingandRestoringNaturalCapitalAcrossScales:LessonsfromtheMillenniumEcosystemAssessment ��Richard B. Norgaard, Phoebe Barnard, and Patrick Lavelle
Chapter 6.AssessingtheLossofNaturalCapital:ABiodiversityIntactnessIndex ��Reinette Biggs and Robert J. Scholes
PART II. Restoring Natural Capital: Experiences and Lessons 55
IntroductionSuzanne J. Milton, James Aronson, and James N. Blignaut
TARGETS
Chapter 7.SettingAppropriateRestorationTargetsforChangedEcosystemsintheSemiaridKaroo,SouthAfrica ��W. Richard J. Dean and Chris J. Roche
Chapter 8.TargetingSustainableOptionsforRestoringNaturalCapitalinMadagascar ��Louise Holloway
Chapter 9.LandscapeFunctionasaTargetforRestoringNaturalCapitalinSemiaridAustralia ��David Tongway and John Ludwig
Chapter 10.GeneticIntegrityasaTargetforNaturalCapitalRestoration:WeighingtheCostsandBenefits 8�Cathy Waters, Andrew G. Young, and Jim Crosthwaite
APPROACHES
Chapter 11.RestoringandMaintainingNaturalCapitalinthePacificNorthwest,USA 9�Andrew Carey
Chapter 12.RestoringNaturalCapitalReconnectsPeopletoTheirNaturalHeritage:TiritiriMatangiIsland,NewZealand 10�John Craig and Éva-Terézia Vesely
Chapter 13.RestoringForageGrasstoSupportthePastoralEconomyofAridPatagonia 11�Martín R. Aguiar and Marcela E. Román
Chapter 14.ACommunityApproachtoRestoreNaturalCapital:TheWildwoodProject,Scotland 1��William McGhee
Chapter 15.AnAdaptiveComanagementApproachtoRestoreNaturalCapitalinCommunalAreasofSouthAfrica 1�9Christo Fabricius and Georgina Cundill
Chapter 16.ParticipatoryUseofTraditionalEcologicalKnowledgeforRestoringNaturalCapitalinAgroecosystemsofRuralIndia 1��P. S. Ramakrishnan
�� Restoring Natural Capital
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Chapter 17.OvercomingObstaclestoRestoreNaturalCapital:Large-ScaleRestorationontheSacramentoRiver 1��Suzanne M. Langridge, Mark Buckley, and Karen D. Holl
Chapter 18.AnApproachtoQuantifytheEconomicValueofRestoringNaturalCapital:ACasefromSouthAfrica 1��James N. Blignaut and Christina E. Loxton
ECONOMIC OPPORTUNITIES: CASE STUDIES
Chapter 19.CapturingtheEconomicBenefitsfromRestoringNaturalCapitalinTransformedTropicalForests 1��Kirsten Schuyt, Stephanie Mansourian, Gabriella Roscher, and Gerard Rambeloarisoa
Chapter 20.RestoringNaturalForeststoMakeMedicinalBarkHarvestingSustainableinSouthAfrica 1�0Coert J. Geldenhuys
Chapter 21.AssessingCosts,Benefits,andFeasibilityofRestoringNaturalCapitalinSubtropicalThicketinSouthAfrica 1�9Anthony J. Mills, Jane K. Turpie, Richard M. Cowling, Christo Marais, Graham I. H. Kerley, Richard G. Lechmere-Oertel, Ayanda M. Sigwela, and Mike Powell
Chapter 22.CostsandBenefitsofRestoringNaturalCapitalFollowingAlienPlantInvasionsinFynbosEcosystemsinSouthAfrica 188Patricia M. Holmes, David M. Richardson, and Christo Marais
Chapter 23.ReturnofNatural,Social,andFinancialCapitaltotheHoleLeftbyMining 198J. Deon van Eeden, Roy A. Lubke, and Pippa Haarhoff
Chapter 24.ProtectingandRestoringNaturalCapitalinNewYorkCity’sWatershedstoSafeguardWater �08Christopher Elliman and Nathan Berry
Chapter 25.MakingtheRestorationofNaturalCapitalProfitableonPrivateLand:KoaForestryonHawaiiIsland �1�Liba Pejchar, Joshua H. Goldstein, and Gretchen C. Daily
PART III. Restoring Natural Capital: Tactics and Strategies 225
IntroductionJames Aronson, Suzanne J. Milton, and James N. Blignaut
VALUATION
Chapter 26.ValuingNaturalCapitalandtheCostsandBenefitsofRestoration ���William E. Rees, Joshua Farley, Éva-Terézia Vesely, and Rudolf de Groot
��Chapter 34 : Mainstreaming the Restoration of Natural Capital
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Chapter 27.ADecision-AnalysisFrameworkforProposalEvaluationofNaturalCapitalRestoration ���Mike. D. Young, Stefan Hajkowicz, Erica J. Brown Gaddis, and Rudolf de Groot
LOCAL AND LANDSCAPE LEVELS
Chapter 28. OvercomingPhysicalandBiologicalObstaclestoRestoreNaturalCapital ��9Karen D. Holl, Liba Pejchar, and Steve G. Whisenant
Chapter 29.OvercomingSocioeconomicObstaclestoRestoreNaturalCapital ���Christo Marais, Paddy Woodworth, Martin de Wit, John Craig, Karen D. Holl, and Jennifer Gouza
GLOBAL LEVEL
Chapter 30.OvercomingObstaclesataGlobalScaletoRestoreNaturalCapital ���Robert J. Scholes, Reinette Biggs, Erica J. Brown Gaddis, and Karen D. Holl
Chapter 31.ManagingOurGlobalFootprintThroughRestorationofNaturalCapitalataGlobalScale ���Joshua Farley, Erica J. Brown Gaddis, William E. Rees, and Katrina Van Dis
POLICIES AND INSTITUTIONS
Chapter 32.MakingRestorationWork:FinancialMechanisms �8�Rudolf de Groot, Martin de Wit, Erica J. Brown Gaddis, Carolyn Kousky, William McGhee, and Mike D. Young
Chapter 33.MakingRestorationWork:NonmonetaryMechanisms �9�William McGhee, John Craig, Rudolf de Groot, James S. Miller, and Keith Bowers
PART IV. Synthesis 303
IntroductionSuzanne J. Milton, James Aronson, and James N. Blignaut
Chapter 34.MainstreamingtheRestorationofNaturalCapital:AConceptualandOperationalFramework �0�Richard M. Cowling, Shirley M. Pierce, and Ayanda M. Sigwela
Chapter 35.RestoringTowardaBetterFuture �1�Suzanne J. Milton, James Aronson, and James N. Blignaut
Glossary �19
References ��9
Editors ���
Contributors ���
Index ���
�� Restoring Natural Capital
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From chapter 34, “Mainstreaming the Restoration of Natural Capital: A Conceptual and Operational Framework,” by Richard M. Cowling, Shirley M. Pierce, and Ayanda M. Sigwela
Protected areas alone will never achieve all of thegoalsand targets required toensure thepersistenceoftheworld’snaturalcapital(e.g.,Rosenzweig�00�)and the delivery of services that intact ecosystemssupply (Kremen and Ostfeld �00�). Consequently,the burden of conserving (and restoring) naturalcapitalwillhave to fall increasinglyonsectorssuchas agriculture, transport, forestry, mining, and ur-bandevelopment(e.g.,HuttonandLeader-Williams�00�).Themainstreamingofbiodiversityconcernsisonestrategyusedbytheconservationcommunitytorespondtothechallengeofensuringthepersistenceofnaturalcapitalandecosystemservices inutilizedlandscapes(Pierceetal.�00�;PetersenandHuntley�00�a).Inessence,mainstreamingmaybedefinedastheprocessofcreatingawarenessofthevalueofnatu-ralcapitalinsectorsthatcurrentlyignoreordiscountit,totheextentthattheywillincorporateconserva-tionactionsintotheirroutineactivities.Akeyconservationactioninproductionlandscapesistherestorationofdegradedortransformednaturalcapital,ashasbeenpointedoutinmanyofthechap-tersinthisbook.Ouraimhereistoprovideacon-
ceptualandoperationalframeworkformainstream-ing the restoration of natural capital in productionlandscapes.
What Is Mainstreaming?
Although mainstreaming is a relative newcomer tothe biodiversity and natural capital lexicon, it is animportantone,sincemainstreamingisacomponentoftheinstitutionsandstrategiesofsomemajorglobalbiodiversity initiatives. For example, the concept isembedded in several articles of the Convention onBiologicalDiversity(ratified199�).Italsounderpinsthe ecosystem service approach of the Millennium Ecosystem Assessment (MA) and is the explicit ob-jectiveoftheStrategicPriority�oftheGlobalEnvi-ronmentalFacility’sGEF-�(�00�)ProgramofWork:“Mainstreaming biodiversity in production land-scapesandsectors—tointegratebiodiversityconser-vation into agriculture, forestry, fisheries, tourism,andotherproductionsectorsinordertosecurena-tional and global environmental benefits” (Petersenand Huntley �00�b). Undoubtedly mainstreaminginitiatives will attract considerable resources fromfundingagenciesoverthenextdecade.AccordingtoPetersenandHuntley(�00�b)theob-jectiveofmainstreaming is “to internalize thegoalsof biodiversity conservation and sustainable use ofbiologicalresourcesintoeconomicsectorsanddevel-opmentmodels,policiesandprograms,andthereforeintoallhumanbehavior.”Cowlingetal.(�00�)iden-tifiedthefollowinglistofdesiredoutcomesofmain-streaming:
The incorporation of biodiversity considerationsintopoliciesgoverningsectoralactivitiesThe simultaneousachievementofgains inbiodi-versity and in the economic sector (the win-winscenario)Sectoralactivitybeingrecognizedasbasedon,ordependenton,thesustainableuseofbiodiversitySituationswheresectoralactivitiesresultinoverallreversalofbiodiversitylosses
Viewed as a process, mainstreaming is a means tospreadtheresponsibilityandbenefitsofconservingbiodiversityandrestoringnaturalcapitalacrossadi-verserangeofsectors.Thisrequirestheidentification
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About This Excerpt
Howcanenvironmentaldegradationbestopp-ed?Howcan itbereversed?Andhowcanthedamage already done be repaired? Restoring Natural Capitalbringstogethersocialandnatu-ralscientistsfromthedevelopedanddevelopingworldstoconsiderthesequestionsandexaminespecificstrategiesforrestoringecosystemgoodsandservicesinnaturalandsocioecologicalsys-tems.Thisexcerptfromthefinalsectionofthebookfocusesontheimportanceofmainstream-ingtherestorationofnaturalcapital,highlight-ingthefactthatrestorationisbecominganes-sentialintervention.
��Chapter 34 : Mainstreaming the Restoration of Natural Capital
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ofscenariosthatprovidebenefitsforboththenaturalcapitalandthetargetedsector,andtheimplementa-tionofactions(forexample, thecreationof institu-tions, including incentives) that enable responsiblebodiestoaccomplishthesescenarios.Mainstreaming interventions may happen at allscalesoforganizationandgeography, fromencour-aging backyard conservation of natural capital in aneighborhood to the impact of a multilateral envi-ronmentalagreementontheglobalocean-transportsystem.Furthermore,awiderangeofactorswillbearthecostsandenjoythebenefits,materialandspiri-tual, associated with mainstreaming, and these willaccrueovershortandlongtimescales(PetersenandHuntley�00�b).There are very few documented cases of effectivemainstreaming.Pierceetal.(�00�)provideexamplesfromSouthAfrica,andPetersonandHuntley(�00�a)from elsewhere in the world. Others, although notexplicitlyconceptualizedassuch,appearinDailyandEllison (�00�), Swingland (�00�), and Rosenzweig(�00�). Pierce et al. (�00�) provide a case illustrat-inghowconservationprioritiescanbemainstreamedintoland-useplanningthroughinterpretationofsci-entificproductsintouser-friendly,user-usefulmapsandguidelines.Inaddition,Knightetal.(�00�)de-scribe how mainstreaming can be integrated into aframeworkforimplementingactionsaimedatsecur-ingconservationpriorities.Thelattertwoareexam-plesofconservationactions thatenableor facilitatetherestorationofnaturalcapitalbyidentifyingresto-rationpriorities.
Conceptual Framework for Mainstreaming the Restoration of Natural Capital
Aconceptualframeworkforrestorationboilsdowntoidentifyingamodelofthedesiredlandscape;inotherwords,whatmixoflandusesandeconomicflowsarerequiredtomeettheneedsofdifferentstakeholders(SalafskyandWollenberg�000)?Restorationimple-mentedinanadhocmannerislikelytofailinachiev-ingdesirableoutcomes(HobbsandNorton199�;seealso chapter �), as has been shown for the ad hocimplementationofotherconservationactions, suchas the location of protected areas (Pressey 199�).Therefore, prior to restoration intervention, stake-holders need to identify an appropriate landscape
modelcharacterizedby requirements for sustainingbiologicalpatternsandprocesses,andforsupportinghuman needs. Effective restoration requires explicitgoalsandtargets(e.g.,HobbsandNorton199�)iden-tifiedinawaythatisconsistentwithaspecificland-scapemodel.Forthemainstreamingofrestorationtohappen,thelandscapemodelmustfacilitatetheidentificationofplausible and compelling win-win scenarios. Thus,farmers must be convinced that the direct and op-portunitycostsofrestoringnative,naturalcapitalontheirfarmswillbeoutweighedbythebenefitsofsuchrestoration, for example, in enhanced productionthrough improved pollination services or reducedsoil erosion (e.g., Kremen and Ostfeld �00�). Simi-larly, restoration interventions aimed at achievingnature conservation goals should be guided by theachievementofexplicitanddefensibletargetsforbio-diversityfeatures,whicharesetintheprocessofsys-tematicconservationplanning(Presseyetal.�00�).While there has been much written on conceptualframeworks, goals, and targets for restoration (e.g.,HobbsandNorton199�), theobvious linkbetweenrestorationandthesystematic,target-driven,conser-vationplanningoflandscapes(MargulesandPressey�000) has only recently been made (e.g., Pressey etal.�00�;CrossmanandBryan�00�).Systematiccon-servation assessments identify those areas of trans-formedordegradednaturalcapitalthatarerequiredtoachievetargetsfortheconservationofbothbiodi-versitypatterns(e.g., species, landclasses)andpro-cesses (e.g., migration corridors). These areas thenbecomedefensibleprioritiesforrestoration,asillus-tratedbyCrossmanandBryan(�00�)foragriculturallandscapesinAustralia.A similar systematic approach is required for therestoration of natural capital for ecosystem servicedelivery(e.g.,KremenandOstfeld�00�;Pierceetal.�00�).Afewconservationassessmentshavetargetedand incorporated the spatial components of eco-system services (e.g., Rouget, Cowling, et al. �00�).However,agreatdealmoreresearchisneededbeforewe can make significant progress in the restorationofnatural capital: (1) thenatural capital—both in-tactanddegraded—inaparticularplanningdomainneeds to be identified and mapped in consultationwiththosestakeholderswhoaredirectbeneficiaries
�� Restoring Natural Capital
SER Restoration Reader
of the services it delivers; (�) the benefits derivedfromthese servicesand their flows to specificben-eficiariesneedtobequantifiedanddisplayedinwaysthataremeaningfultostakeholders;(�)targetsneedtobesetforeachcomponentoftheregion’snaturalcapital in a way that is consistent with a landscapemodel(forexample,acertainnumberofhectaresofhealthy watershed are required to ensure a sustain-ablewatersupplyoveraspecifiedperiod);(�)targetshortfalls should be identified as priorities for res-toration; and (�) mechanisms should be sought tomainstreamtherestorationoftheseareasintothosesectorsthatbenefitfromtheservicesprovidedbythenaturalcapital.The major advantage of systematic restoration toachievethegoalsforaspecificlandscapemodelisthatitistargetdrivenand,therefore,defensible,efficient,andeffective(CrossmanandBryan�00�).Theseat-tributesarelikelytogreatlyfacilitatemainstreaming,especiallywhentheactorsarecash-strappedgovern-mentagenciesorprofit-motivatedcorporations.An Operational Framework for Mainstreaming theRestorationofNaturalCapitalCowlingetal.(�00�)developedanoperationalframe-work for mainstreaming biodiversity, informed byelevenSouthAfricancasestudiespresentedinPierceetal.(�00�).Theframeworkissufficientlybroadtoaccommodate restoration interventions; along with
theestablishmentofprotectedareasandeffectivesoiland water conservation, restoration is another toolforconservingbiodiversity.Theframeworkcompris-esfourmajorcomponents:
Prerequisites essential for mainstreaming to takeplaceStimuli, external and internal to the sector, thatcatalyzeawarenessoftheneedformainstreamingMechanisms that initiate, enable, or drive main-streamingOutcomesthataremeasurableindicatorsoftheef-fectivenessofmainstreaming
In the framework, the mainstreaming process wasdescribed as follows: “Given that certain prerequi-sitesareinplace,asetofspecificstimulicancatalyseactivitieswhichthenleadtotheidentificationofap-propriatemechanisms,withthenetresultthateffec-tive mainstreaming, as measured by outcomes, willhappen”(Cowlingetal.�00�).
Excerpted from Restoring Natural Capital edited by James Aronson, Suzanne J. Milton, and James N. Blignaut. Copyright © 2007 by Island Press. Excerpted by permission of Island Press. All rights reserved. No part of this excerpt may be reproduced or reprinted without permis-sion in writing from the publisher. Island Press grants permission to forward this unaltered electronic document to friends, colleagues, and other interested parties.
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RivER futuRES
River FuturesAn Integrative Scientific Approach to River Repair
EditedbyGaryJ.BrierleyandKirstieA.Fryirs
Cloth,$80.00,ISBN9�8-1-�9���-11�-8
Paper,$�0.00,ISBN9�8-1-�9���-11�-�
�008.���pages.8x10
Contents
Preface xiii
PART I. The Emerging Process of River Repair 1
Chapter 1.MovesTowardanEraofRiverRepair �Gary J. Brierley and Kirstie A. Fryirs
TheEmergingProcessofRiverRepair �TheEmergenceofIntegrativeRiverScience 8FramingOurGoalsintheProcessofRiverRepair 11StructureoftheBook 1�
Chapter 2. VisionGeneration:WhatDoWeSeektoAchieveinRiverRehabilitation? 1�Darren Ryder, Gary J. Brierley, Richard Hobbs, Garreth Kyle, and Michelle Leishman
UsingaGuidingImagetoSetRehabilitationGoals 1�ScientificConsiderationsinVisionGeneration 18AssessingRehabilitationSuccess 18SocioeconomicConsiderations:AnInclusiveApproachtoVisionGeneration �0
�8 River Futures
SER Restoration Reader
IncorporatingaGuidingImageintoSuccessfulRiverRehabilitationPractice ��Conclusion ��
Chapter 3.TurbulenceandTrainWrecks:UsingKnowledgeStrategiestotheEnhanceApplicationofIntegrativeRiverSciencetoEffectiveRiverManagement �8Andrew Boulton, Hervé Piégay, and Mark D. Sanders
SourcesofTurbulence �8ReducingTurbulencewithSharedBeliefs:TenetsandCommitments �9SeekingSolvableProblems:ComparativeAnalysisofKnowledgeStructures �1FourLogicalStepstoEvaluateKnowledgeStructures ��StrategiesforConstructingSolvableProblems:DifficultiesandPotentialSolutions ��Conclusion ��
PART II. An Integrative Scientific Perspective to Guide the Process of River Repair 41
Chapter 4.TheSpatialOrganizationofRiverSystems �� Carola Cullum, Gary J. Brierley, and Martin Thoms
PerspectivesontheSpatialOrganizationofRiverSystems ��AnIntegratedPerspective:AnalyzingRiverSystemsasSpatiallyNestedHierarchies ��ChallengesinDeterminingScalesandPatchBoundaries ��BioticImplicationsoftheSpatialArrangementofGeomorphicProcessDomains �8ManagementImplications �9Conclusion �1
Chapter 5.WorkingwithChange:TheImportanceofEvolutionaryPerspectivesinFramingtheTrajectoryofRiverAdjustment �� Gary J. Brierley, Kirstie A. Fryirs, Andrew Boulton, and Carola Cullum
ContemporaryRiverDynamicsinTheirEvolutionaryContext ��ScalesandFormsofGeomorphicAdjustment �9LinkagesbetweenAbioticandBioticAdjustmentsalongRivers �1ConceptualizingRiverEvolutionandRecoveryasaBasisforManagementPlanningandAction ��ExamplesofRiverTrajectories ��Place-BasedConceptualModeling ��Conclusion 81
Chapter 6.EcologicalFunctioninRivers:InsightsfromCrossdisciplinaryScience 8� Sarah Mika, Andrew Boulton, Darren Ryder, and Daniel Keating
InteractionsbetweenStructureandFunction 8�InteractionsbetweenStructureandFunctioninSpaceandTime 8�ConnectivitywithinRiverineEcosystems 90ExamplesofCrossdisciplinaryResearchonEcologicalFunction 9�Conclusion 9�
Chapter 7.PrinciplesofRiverConditionAssessment 100 Kirstie A. Fryirs, Angela Arthington, and James Grove
�9Chapter 8 : Social and Biophysical Connectivity of River Systems
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PurposesofRiverConditionAssessments 101EcosystemIntegrityasaBasisforAssessingBiophysicalRiverCondition 101IntegratingAbioticandBioticFactorsinAssessmentsofRiverCondition 10�WhatIsNaturalorExpected?DefiningReferenceConditions 10�IndicatorsThatProvideaReliableandRelevantMeasureoftheBiophysicalConditionofRivers 108ConsiderationsintheDesignandApplicationofIntegrativeFrameworksforAssessingBiophysicalCondition 110IntegratingToolsforAssessingRiverCondition 111Conclusion 118
Chapter 8.SocialandBiophysicalConnectivityofRiverSystems 1�� Mick Hillman, Gary J. Brierley, and Kirstie A. Fryirs
ConnectivityandRiverHealth 1��Forms,Patterns,andChangestoPhysical(Dis)Connectivity 1��Social(Dis)Connectivity 1�9ContrastingSub-CatchmentsfromtheHunterValley,NewSouthWales 1��InterbasinTransfers:TheSnowyHydroScheme 1��(Dis)Connectivity:ThemesforIntegrativeRiverManagement 1�8Synthesis:Sustainability,Health,Justice,andPolicyinAddressing(Dis)Connectivity 1�0Conclusion 1��
PART III. International Rerspectives on the Process of River Repair 147
Chapter 9.TheAustralianRiverManagementExperience 1�9 Kirstie A. Fryirs, Bruce Chessman, Mick Hillman, David Outhet, and Alexandra Spink
SettingtheScene:TheAustralianLandscapeandHistoricalSetting 1�9BiophysicalThemesinAustralianRiverManagementPractice:WhatIsAchievable? 1��TheOrganizationalContextofAustralianRiverManagementPractice:TheCapacitytoDoSomething 1��SocialThemesinAustralianRiverManagementPractice:CommunityWilltoDoSomething 1��IntegrationandFutureChallenges 1��Conclusion 1�9
Chapter 10.RiverManagementintheUnitedStates 1�� Ellen Wohl, Margaret Palmer, and G. Mathias Kondolf
HowHealthyAreRiversintheUnitedStates? 1��PolicyandLegalFramework 1��ContemporaryPressuresandConstraintsonWaterResources 1��LikelyFutureInfluencesonRiverManagement 180StrategiesforRiverProtectionandRehabilitation 180ExamplesofRiverRehabilitation 18�Conclusion 19�
�0 River Futures
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Chapter 11.IntegrativeRiverScienceandRehabilitation:EuropeanExperiences �0� Hervé Piégay, Larissa A. Naylor, Gertrud Haidvogl, Jochem Kail, Laurent Schmitt, and Laurent Bourdin
TheEmergenceofIntegrativeRiverScienceinEuropeanCountries �0�IntegrativeSciencesinPioneerRehabilitationPrograms �0�ChallengesApproachingImplementationoftheEuropeanWaterFrameworkDirective �1�Conclusion �19
Chapter 12.TheLightandDarkofSabo-DammedStreamsinSteeplandSettingsinJapan ��� Tomomi Marutani, Shun-ichi Kikuchi, Seiji Yanai, and Kaori Kochi
WhyHaveWeDevelopedtheSaboDamCountry? ���DiscontinuityofGeoecologicalInteractionsalongRiverCourses ���ManagementofDammedStreams ���Conclusion ���
Chapter 13.ApplicationofIntegrativeScienceintheManagementofSouthAfricanRivers ��9 Kate M. Rowntree and Leanne du Preez
SouthAfricanWaterLegislation,Agenda�1,andSouthAfricanRiverManagement ��0TheReserveasanExampleofSouthAfricanManagementFrameworks ��1FutureFluvialGeomorphologies ���IntegrativeScienceandtheFutureofSouthAfricanRiverManagement ��0Conclusion ���
PART IV. Managing the Process of River Repair 257
Chapter 14.RestoringUncertainty:TranslatingScienceintoManagementPractice ��9 Mick Hillman and Gary J. Brierley
SourcesofUncertaintyintheManagementofRiverSystems ���TheAssessmentofConditioninRiverManagement:CharacteristicsandUncertainty ���UncertaintyandSustainability ��8LivingwithUncertaintyintheEraofRiverRepair ��0Conclusion ��0
Chapter 15.RiverFutures ��� Gary J. Brierley, Kirstie A. Fryirs, and Mick Hillman
TheEmergingProcessofRiverRepair ���UsingCoherentScientificInformationtoGuidetheProcessofRiverRepair ���ManagingtheProcessofRiverRepair ��8Conclusion �8�
About the Contributors �8�
Index �99
�1Chapter 8 : Social and Biophysical Connectivity of River Systems
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From chapter 8, “Social and Biophysical Connec-tivity of River Systems,” by Mick Hillman, Gary J. Brierley, and Kirstie A. Fryirs
Place is the location . . . where the social and the natural meet. — Dirlik 2001, 18
Successfulintegrativerivermanagementrequiresanunderstandingofthelinksbetweennaturalandcul-turallandscapes,ensuringthatinstitutionalandcom-munityvaluesaremeaningfully incorporatedintheprocess of environmental repair (Harris �00�). Co-herentapproaches to theassessmentof riverhealthintegrate biophysical and social dimensions of en-vironmentalcondition,buildingon therelationshipbetween healthy rivers as products of, and in turnpromoting, healthy societies. Understanding andworkingwiththeconceptofconnectivityacrossboththebiophysicalandsocialdimensionsisacorecom-ponent of this relationship. A connected approachtointegrativerivermanagementaimsforadialoguebetween scientific understanding and communityvalues.Applying thisprinciple thereforemeansun-derstanding both catchment-scale biophysical link-agesandcommunityperceptionsofwhatconstitutesa“healthyriver.”Suchunderstandingsarespecifictotimeandplace,militatingagainst theapplicationofgenericmodelsandassumptions.
Contemporary perceptions of river health are con-tingentuponpresentandpastconnectionsbetweenpeople and their river. They encompass a range ofpotentialusesandvalues.However,inthelargebodyofliteratureinfluencedbyEurocentricideasofland-scape,healthyriversareoftenromanticizedassingle,continuous, constantly flowing channels (Kondolf�00�). Postcolonial societies have afforded rivers alimited range of uses, and systems are expressed ashealthyonlyifconditionssuitablefortheseusesaremaintained.Disconnectioninariversystem,wheth-er it is thepresenceof isolatedpools inriverchan-nelsorephemeraltributaries,hasbeenportrayedasanundesirableandunsustainablestate(Kondolfetal.�00�).Thiscontrastswiththerecognitionofvariableandchangingformsofconnectionanddisconnectionin many indigenous cultures (Smolyak �001; James�00�).Recognitionofthevariableandchangingpat-ternsofconnectivityacrosstimeandspace,andbe-tween social and biophysical dimensions, is a corecomponentofintegrativerivermanagement.Whether appraised in biophysical or social terms,landscapes, ecosystems, and communities can berelativelyconnectedordisconnected.Forriverman-agementtobesuccessfulandrelevantitisimportantto recognize thatbiophysicaldisconnectionmaybenaturalandhealthyatagiventimeandplace.Forthisreasonweusetheterm(dis)connectivitytorefertodynamicpatternsofconnectionanddisconnection.Forexample,disconnectedandisolatedpartsofriv-er systems may shelter distinct genetic populationsof speciesandunique floristicand faunalattributes(Sheldonetal.�00�;Bunnetal.�00�).Likewise,hu-man(dis)connectivitywithrivershasoftenbeenme-diatedbyculturalfactors,particularlyinindigenoussocietiesthroughtaboos,totems,andsacredsitesthatare the result of co-evolution with landscapes overmanygenerations(Rose1999;Townsendetal.�00�).However,inmorerecenthistory,biophysicaldiscon-nection has often been imposed through the con-structionofbarriers,whilesocialdisconnectionhasresulted fromappropriationandenclosureof ripar-ianlandorinresponsetorapidlydevelopingpercep-tionsby local communitiesof the river aspolluted,unhealthy,orasbringerofdamagingfloods.Presentday disconnection is often the legacy of an earlierfocus on narrow and exclusive uses of the river forirrigation, discharge of effluent, or navigation. This
About This Excerpt
River Futures provides a holistic overview ofconsiderationsthatunderpintheuseofscienceinrivermanagement,emphasizingcross-disci-plinaryunderstanding.Thisexcerptfromchap-ter8introducesthenotionof“connectivity”asan integrating theme, relating biophysical no-tions of landscape and ecosystem connectivity(or disconnectivity) to social relationships toplace.
�� River Futures
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typeofdisconnectionisreferredtobyWard(�001)as“geo-environmentaldisconnection,”theproductoftechnocentriceffortstoforgelandscapesforagricul-ture, industry,andrecreation.Conversely,biophysi-cal and social connections may have been imposedthrough the development of irrigation systems insemi-aridlandscapes.
In this chapter, we argue that imposed, arbitrary(dis)connectivitybasedonanarrowlydefinedorex-clusiveuseofwaterisunhealthyinrivermanagementand is ultimately unsustainable and unjust. Such(dis)connectivityreducescommunityunderstandingof,andconcernfor,ourrivers,whileallowingdomi-nantandenvironmentallydamagingusesandprac-ticestocontinue.Italsopromotesfeelingsofinequity,distributing costs and benefits through top-downdecisionsordecrees.Ontheotherhand,broadandholistic(dis)connectivityinitsmanyformsstronglyimplies the convergence of social and biophysicalperspectives and acknowledgment of a wider rangeofvaluesasavitalstepintheprocessofriverrepair.Transdisciplinary work on links between ecologicalandcommunityhealthandwell-beingindicatesthatthehealthyappreciationoftheinherentdiversityandvariabilityofriversystemsisanintegralpartofheal-ingour relationship to thenaturalworld (Costanzaand Mageau 1999; Connor et al. �00�). Based ontheseguidingprinciples,thischapterusesatransdis-ciplinaryandplace-basedanalysisofbiophysicalandsocial(dis)connectivityto:
Examinethebroadlinksbetweenconnectivityandriverhealth.
Describe the biophysical and social forms andchanging patterns of connection and disconnec-tionwithinariversystemandbetweenpeopleandthatsystem.
Analyze key themes in the interrelationship be-tween the biophysical and social dimensions of(dis)connectivitythroughcaseexamples.
Highlightimplicationsofthesethemesinthede-velopment of just and sustainable approaches tothemanagementofhealthyrivers.
1.
�.
�.
�.
Connectivity and River Health
Theviewofriverhealthoutlinedinchapter�focusesonexternal,biophysical,andverifiableindicatorsofrivercondition.Oftensuchindicatorsarespecifictoparticulardisciplinesandscales.However,giventhatrivers epitomize the links between landscapes andecosystems (Jungwirth et al. �00�), a practical un-derstandingofbiophysicallinkagesiscrucialinpro-ducing the “mature knowledge” that is increasinglyrequiredforeffective integratedecosystemmanage-ment(Lake�001;Dunn�00�).Thisisinitselfama-jorchallenge,sincecomplexindicatorsofrivercondi-tion,suchasconnectivityitself,haveproveddifficulttoquantifybothforconceptualreasonsandbecauseofscientificconcernovervaliddescriptorsandrigorofresultantdata(Dunn�00�).Acomplementarybutdistinctviewofriverhealthisonebasedontheideaofsocialconnection,inwhichhealth is about people developing, maintaining, orlosinginteractionwiththeriver.Integraltothinkingabout the way people connect and disconnect withriversisthebroadgeographicalnotionofplaceasso-cially constructed (Massey �00�), and of a sense ofplaceas individually interpreted rather thanhavingoneparticular“essence.”Thenotionof“place-identi-ty”hasbeenusedtodescribethissocialdimensionofconnection:“itcanbesaidtorepresentthephysicalsettings’importanceforaperson’sidentity.Researchinplace-identitysuggeststhatanindividualhasmorecomplex relations to the environment than simplylivinginit”(Wester-Herber�00�,111).Connectionthroughplace-identityisfundamentaltocommunity engagement in river management pro-grammes,fosteringasenseofcommitment,buildingsocialcapital,andallowinglocalknowledgearoleinplanning(Hillmanetal.�00�;ThompsonandPep-perdine�00�).Place-identityalsohighlightstheneedtothinkofhealthintermsofbothbiophysicalindica-torsandhuman-nature relationships (Brierleyetal.�00�b).However,theestablishmentofplace-identityisanecessaryprerequisiteratherthananinherentlysufficientconditionforriverhealth—thereisnorea-sontoarguethatsomegooduse-valuescreateplace-identity and others do not. Our point here is thatwithoutsuchconnection,therelationshipsthatsus-tain integrativerivermanagementcannotbe forgedandthatnarrowandexclusivevalueswillprevail.
��Chapter 8 : Social and Biophysical Connectivity of River Systems
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Thenexusbetweenbiophysicalandcommunityhealthin major river rehabilitation strategies has been ex-pressedinpracticeinseveralforms.Forinstance,theLoireVivante (LivingLoire)programaims to “leadpeople back to the river,” while the Mersey BasinCampaignincludesinitsvisionthegoalofincreasingthevaluingoftheriverbyitscommunity.TheDutchpolicyof“SpacefortheRiver”aimstomaintainfloodprotectioninthefaceofincreaseddesigndischarges,whileatthesametimeconservinglandscape,ecolog-ical,andhistoricalfeatures(CalsandvanDrimmelen�000).TheVictorianRiverHealthStrategyincludestheobjectiveof“maintainingtherivers’placeinourcollectivehistory”withtheoverallaimthat“ourcom-munitieswillbeconfidentandcapable,appreciating
thevaluesoftheirrivers,understandingtheirdepen-dencyonhealthyriversandactivelyparticipatingindecision-making”(VictorianGovernment�00�,�).The next sections develop a conceptual frame-work for exploring forms of biophysical and social(dis)connectivity in river systems, providing a lensonthisintegrativeapproachandonacondition-con-nectionnotionofhealth.
Excerpted from River Futures: An Integrative Scientific Approach to Riv-er Repair edited by Gary J. Brierley and Kirstie A. Fryirs. Copyright © 2008 by Island Press. Excerpted by permission of Island Press. All rights reserved. No part of this excerpt may be reproduced or reprinted without permission in writing from the publisher. Island Press grants permission to forward this unaltered electronic document to friends, colleagues, and other interested parties.
laRgE-ScalE EcoSyStEm REStoRation
Large-Scale Ecosystem RestorationFive Case Studies from the United States
EditedbyMaryDoyleandCynthiaA.Drew
Cloth,$�0.00,ISBN9�8-1-�9���-0��-1
Paper,$��.00,ISBN9�8-1-�9���-0��-8
�008.���pages.�x9
Maps,figures,index
Contents
Introduction: TheWatershed-Wide,Science-BasedApproachtoEcosystemRestoration xi Mary Doyle
PART I. The Everglades 1
Chapter 1.TheChallengesofRestoringtheEvergladesEcosystem �Terrence “Rock” Salt, Stuart Langton, and Mary Doyle
Chapter 2.EvergladesEcology:TheImpactsofAlteredHydrology ��Thomas L. Crisman
Chapter 3.RiversofPlansfortheRiverofGrass:ThePoliticalEconomyofEvergladesRestoration ��Stephen Polasky
PART II. The Platte River 55
Chapter 4.NegotiatingforEndangeredandThreatenedSpeciesHabitatinthePlatteRiverBasin �9 David M. Freeman
Chapter 5.PlatteRiverBasinEcology:AThree-DimensionalApproachtoAdaptiveManagement 89Thomas L. Crisman
Chapter 6.NavigatingtheShoals:CostsandBenefitsofPlatteRiverEcosystemManagement 100Stephen Polasky
��Chapter 6: Navigating the Shoals: Costs and Benefits of Platte River Ecosystem Management
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PART III. The California Bay-Delta 109
Chapter 7.California’sDelta:TheChallengesofCollaboration 11�David Nawi and Alf W. Brandt
Chapter 8.TheEcologyofBay-DeltaRestoration:AnImpossibleDream? 1��Thomas L. Crisman
Chapter 9.WaterFights:TheEconomicsofAllocatingScarceWaterandBay-DeltaRestoration 1�0Stephen Polasky
PART IV. The Chesapeake Bay 171
Chapter 10.TheCultureofCollaborationintheChesapeakeBayProgram 1��Mary Doyle and Fernando Miralles-Wilhelm
Chapter 11.AnEcologicalPerspectiveonManagementoftheChesapeakeBay �0�Thomas L. Crisman
Chapter 12.MurkyWatersandMurkyPolicies:CostsandBenefitsofRestoringChesapeakeBay �1� Stephen Polasky
PART V. The Upper Mississippi River 225
Chapter 13.TheUpperMississippiRiverandtheArmyCorpsofEngineers’NewRole:WillCongressFundEcosystemRestoration? ��9Cynthia A. Drew
Chapter 14.UpperMississippiRestorationEcology:PuttingTheoryintoPractice ��9Thomas L. Crisman
Chapter 15.ComparingApplesandOranges?CostsandBenefitsofUpperMississippiRiverSystemRestoration ��9Stephen Polasky
Conclusion:AssessingEcosystemRestorationProjects �91Mary Doyle
AbouttheAuthors �01
AbbreviationsandAcronyms �0�
�� Large-Scale Ecosystem Restoration
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From chapter 6, “Navigating the Shoals: Costs and Benefits of Platte River Ecosystem Management,” by Stephen Polasky
ThepresettlementPlatteRiverwasawide,shallow,muddy,slow-movingriverwithcomplex,braidedchannels.Earlyattemptstousetherivertotransportfursandothergoodsmet with frustration and failure, as boats frequently ranagroundandhadtobedraggedovernumeroussandbars.Nineteenth-century humorist Artemus Ward describedthePlatteas“amilewideandaninchdeep”andsaidthatit would be a considerable river if turned on edge (Wil-loughby�00�).AttemptingtonavigateasuccessfulplanforecosystemmanagementonthePlatteisevenmoredifficultthanattemptingtonavigateafullyloadedboatontheriveritself. Like the Platte’s physical description, negotiationstoreachagreementonhowtomanagewaterflowsinthePlatteRiverarewide-ranging;oftenslowmoving;involvecomplex,interconnectedsetsofinterestgroups;andhaveanunclear(muddy)resolution.WhilethePlatteRiverhasnotprovedtobeimportantfortransportation,itisvitallyimportantinotherways.ThePlatteflowsthroughoneofthemostaridregionsofthecountry,fromcentralandeast-ernColoradoandWyomingthroughwesternandcentralNebraska,beforeemptyingintotheMissouriRiverattherelatively wetter, eastern end of Nebraska. In dry years,thePlatteistheonlysignificantsourceofsurfacewaterinmuchofitsdrainagebasin:“ThePlatteRiverisaconsis-tent sourceof relativelywell-wateredhabitat . . .with itswatersourceindistantmountainswatershedsthatarenotsubjecttodroughtcyclesassevereasthoseoftheNorth-ernPlains”(NRC�00�,8).Assuch,waterfromthePlatteRiverandthehabitatalongtheriverisinhighdemandby
peopleandotherspecies.Whattheriver isgoodforandhowitshouldbemanageddependonone’spointofview.TherearenumerouscomplexinterestgroupswithastakeinwatershedmanagementalongthePlatte; it isusefultocategorize theminto threemaingroups: (1)urbanwaterusers,(�)agriculturalwaterusers,and(�)environmentalinterests. The first two groups have primary interests inwaterusesthatrequirewithdrawalofwaterfromtheriver,whiletheenvironmentalinterestsseektomaintainnaturalflowregimesandhabitatalongtherivernecessarytosup-port species, especially three federally listed endangeredspecies: whooping crane, interior least tern, and pallidsturgeonandonethreatenedspecies:pipingplover.
Urban and Agricultural Water Use
WithinthePlatteRiverBasinalongtheFrontRangeoftheRockyMountainsarerapidlygrowingmetropolitanareasfromDenvertoCheyenne.Theareaisattractivebecauseof its sunny weather and the nearby mountains’ beautyand recreationalopportunities. InColorado, thepopula-tionlivingintheSouthPlatteBasinincreasedby��per-cent between 1990 and �00�, from �.� million to over �million(ThorvaldsonandPritchett�00�).Rapidpopula-tion growth is expected to continue. Population withintheSouthPlatteBasininColoradoisexpectedtogrowbyalmost � million people (a ��-percent increase) between�000 and �0�0 (DiNatale et al. �00�). More people willmean more water demands for residential, commercial,andindustrialuses.TotalwaterdemandintheSouthPlatteBasininColoradoisexpectedtoincreaseby��0,000acre-feetperyear,roughlya�0-percentincreasefrom�000to�0�0(DiNataleetal.�00�).
While urban water uses are growing rapidly, agricultureremainsthedominantwateruserinthePlatteRiverBasin.WateristhelimitingfactorforagriculturalproductioninmuchofthewesternUnitedStates,certainlythecaseinthePlatteRiverBasin.Rainfallinmuchofthebasinaveragesbetween 10 and �0 inches per year, too little to supportagricultural production without irrigation. (“Dryland”agriculture,whichdoesnotrequireirrigation,ispracticedbutrequiresfallowyearsbetweencropproductionyears.)OnlynearthemouthofthePlatteineasternNebraskaisrainfallsufficienttosupportannualcropproductionwith-outsignificantirrigation.
In the western states as a whole, agriculture accountedforover��percentofallsurfacewaterdiversionsin1990(CBO199�).Duringthesameyear,municipalandindus-
About This Excerpt
Representing a variety of geographic regionsand project structures, the case studies in thisvolumeshed lighton thecentral controversiesfacedbylarge-scaleecosystemrestorationfrompolitical,ecological,andeconomicperspectives.Inthisexcerptfromchapter�,StephenPolaskyintroduces the complex interest groups with astakeinwatershedmanagementalongthePlatteRiver.
��Chapter 6: Navigating the Shoals: Costs and Benefits of Platte River Ecosystem Management
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trialusesaccountedforroughly10percentoftotalsurfacediversions(CBO199�).IntheSouthPlatteBasininColo-rado,agriculturaldiversionsarecurrently�.�timesthoseof municipal and industrial uses (DiNatale et al. �00�).Approximately�millionacresoflandareirrigatedinthePlatteRiverBasin(NRC�00�).Whileagricultureusesthelion’sshareofthebasin’swater,theeconomiccontributionoftheagriculturalsectortotheoveralleconomyissmall.Agriculture contributed less than 1 percent of the totalvalueofannualrevenuesfromagriculturalproductsintheSouthPlatteBasininColorado(ThorvaldsonandPritchett�00�).Agricultureconstitutesahigherpercentageof theeconomyinNebraska,�.�percentoftotalgrossstateprod-uctin�00�(BEA�00�),becauseagriculturalproductionislargerandtherestoftheeconomyissmaller.
WaterforagriculturaluseinthePlatteRiverBasinislikelytodeclineover timebecauseagriculturecannotcompeteeconomicallyorpoliticallywithwaterdemandforurbanuses,andoverallwaterdiversionswillbelimitedbyenvi-ronmentalconcerns.IntheSouthPlatteBasininColorado,irrigatedacresareexpectedtofallbybetween1��,000to���,000acresfrom�000to�0�0(DiNataleetal.�00�).
AswellnotedbyDavidFreeman(seeChapter�,thisvol-ume), though diverting water from agriculture to otherhigher valued uses is supported by economic logic, thedryingofagriculturewillhavenegativeconsequencesforsmall townsandruralareasdependentuponagriculture.ManysmallcommunitiesintheGreatPlainshavesufferedfrom declining populations and stagnant economies fordecades.Lossofwaterforirrigationwillhastenthedecline
and literally drain much of the remaining vitality fromthesecommunities.
Therecentsurgeofinterestintheproductionofrenewableenergyfrombiomasscrops(biofuels)mightkeepagricul-tureafloat intheregion.Theincreaseddemandforcornfrom ethanol production helped push corn prices fromaround$�perbushelinearly�00�tonearly$�perbushelin early �00� before prices fell back slightly (ERS �00�).Theincreaseddemandandhigherpriceforcornmakeitsproductionmoreprofitableandwateruseforagriculturemorevaluable.Callsforevenhigherproductionofbiofu-els inthefuturecouldresult infurtherincreases inagri-culturalprices.IntheStateoftheUnionAddressin�00�,PresidentGeorgeBushcalledforincreasingrenewableandalternative fuelproduction to��billiongallonsby�01�.Bywayofcontrast,ethanolproduction in�00�was�.8�billiongallons(RFA�00�.EthanolproductioninthePlatteRiverBasin,however,willlikelybelimitedbywateravail-ability.Inadditiontowaterusedforirrigationofcornandothercrops,waterforethanolproductionamountedto�.�gallons of water per gallon of ethanol produced in �00�(IATP�00�).
Excerpted from Large-Scale Ecosystem Restoration: Five Case Studies from the United States edited by Mary Doyle and Cynthia A. Drew. Copyright © 2008 by Island Press. Excerpted by permission of Island Press. All rights reserved. No part of this excerpt may be reproduced or reprinted without permission in writing from the publisher. Island Press grants permission to forward this unaltered electronic document to friends, colleagues, and other interested parties.
old fiEldS
Old FieldsDynamics and Restoration of Abandoned Farmland
EditedbyVikiA.CramerandRichardJ.Hobbs
Cloth,$80.00,ISBN9�8-1-�9���-0��-9
Paper,$�0.00,ISBN9�8-1-�9���-0��-�
�00�.���pages.�x9
Tables,figures,manuscriptcasestudies,index
Contents
Acknowledgments ix
Chapter 1. WhyOldFields?SocioeconomicandEcologicalCausesandConsequencesofLandAbandonment 1Richard J. Hobbs and Viki A. Cramer
PART I. Old Fields and the Development of Ecological Concepts 15
Chapter 2.OldFieldSuccession:DevelopmentofConcepts 1�Richard J. Hobbs and Lawrence R. Walker
Chapter 3.OldFieldsasComplexSystems:NewConceptsforDescribingtheDynamicsofAbandonedFarmland �1Viki A. Cramer
PART II. Case Studies from Around the World 47
Chapter 4.ImplicationsofLandUseHistoryforNaturalForestRegenerationandRestorationStrategiesinPuertoRico �1Jess K. Zimmerman, T. Mitchell Aide, and Ariel E. Lugo
�9Chapter 6: Old Field Vegetation Succession in the Neotropics
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Chapter 5.ProcessesAffectingSuccessioninOldFieldsofBrazilianAmazonia ��Gislene Ganade
Chapter 6.OldFieldVegetationSuccessionintheNeotropics 9�Karen D. Holl
Chapter 7.PatternsandProcessesofOldFieldReforestationinAustralianRainForestLandscapes 119Peter D. Erskine, Carla P. Catterall, David Lamb, and John Kanowski
Chapter 8.SuccessiononthePiedmontofNewJerseyandItsImplicationsforEcologicalRestoration 1��Scott J. Meiners, Mary L. Cadenasso, and Steward T. A. Pickett
Chapter 9.SuccessionandRestorationinMichiganOldFieldCommunities 1��Katherine L. Gross and Sarah M. Emery
Chapter 10.OldFieldSuccessioninCentralEurope:LocalandRegionalPatterns 180Karel Prach, Jan Lepsˇ, and Marcel Rejmánek
Chapter 11.DynamicsandRestorationofAbandonedFarmlandandOtherOldFieldsinSouthernFrance �0�Pascal Marty, James Aronson, and Jacques Lepart
Chapter 12.LandAbandonmentandOldFieldDynamicsinGreece ���Vasilios P. Papanastasis
Chapter 13.OldFieldDynamicsontheDrySideoftheMediterraneanBasin:PatternsandProcessesinSemiaridSoutheastSpain ���Andreu Bonet and Juli G. Pausas
Chapter 14.RestorationofOldFieldsinRenosterveld:ACaseStudyinaMediterranean-typeShrublandofSouthAfrica ���Cornelia B. Krug and Rainer M. Krug
Chapter 15. ProspectsfortheRecoveryofNativeVegetationinWesternAustralianOldFields �8�Viki A. Cramer, Rachel J. Standish, and Richard J. Hobbs
PART III. Synthesis: Old Field Dynamics and Restoration 307
Chapter 16.OldFieldDynamics:RegionalandLocalDifferences,andLessonsforEcologyandRestoration �09Richard J. Hobbs and Viki A. Cramer
AbouttheEditors �19
AbouttheContributors ��1
�0 Old Fields
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From chapter 6, “Old Field Vegetation Succession in the Neotropics,” by Karen D. Holl
Factors Affecting Forest Succession in Old Fields
It isnecessaryto identifyfactorsthataffecttherateanddirectionofsuccessionatarangeofspatialscalesinordertodeveloprestorationstrategiestoaccelerateorredirectsuccessionaltrajectories.Icategorizethefactors affecting forest succession into three broadcategories(Figure�.�):theunderlyingabioticgradi-ents(rainfall,temperature,andsoil),thecompositionofsurroundinglandusemosaic,andthetypeandin-tensityofpastlanduse.Idiscussindetailhoweachofthesegeneralfactorsaffectstherateanddirectionoftropicaloldfieldsuccession.
Underlying Abiotic Gradients
Much of the difference in the rate and direction ofsuccessioninneotropicaloldfieldscanbeexplainedbyanthropogenic factors, suchassurrounding landuseandlandusehistory(discussedlater),butthesefactorsareoverlainonanumberofabioticgradients,primarilyrainfall,temperature,andsoiltype,whichstronglyinfluenceforestrecovery.Tropicalforestsfallalongarainfallgradientrangingfromupto�–8mofrainfallevenlydistributedthroughouttheyearinthewettestsitesto<1.�mofrainfallwith>�monthsofdryseason in thedriest sites.Theamountandsea-sonalityofrainfallareprimaryevolutionarydriversfortropicalforestplants,andtheyprofoundlyinflu-enceoldfieldsuccession.Anumberoftropicalplantlife-historytraitsthatvaryacross the rainfall gradient strongly affect recovery.First,driertropicalforestshaveahigherpercentageof wind-dispersed seeds (Ewel 19��; Janzen �00�;Vieira and Scariot �00�). For example, in a reviewofstudiesacrossaprecipitationgradient,VieraandScariot(�00�)report�0%–��%wind-dispersedspe-ciesintropicaldryforestand<1�%wind-dispersedspeciesintropicalmoistorwetforest.Dryforestre-covery may therefore be less dispersal limited thanmoist tropical forests (Janzen �00�). Second, al-though resprouting after disturbance is a commonplantadaptationthroughoutthetropics,resproutingismorecommonintropicaldryforests,wherewaterlimitation favorsan increasedenergy investment inroots(Ewel19��;VeskandWestoby�00�;VieiraandScariot�00�).Third,seedlingmortalityduetodesic-cationismuchhigherindryforestsandvariesagreat
deal interannually, dependingon rainfall fluctuations (VieiraandScariot�00�),whichmakesestablishment from seed lesspredictable. Likewise, seedlinggrowth may be slower due tolackofwater.Thereissomeevi-dence that dry forests may bemoreresilientbecauseoflowerstructural complexity, greaterwind dispersal, and more fre-quentresprouting;nonetheless,it is impossible to generalizeabouttherateofrecoveryofallforests across a rainfall gradi-
About This Excerpt
Landthathasbeentransformedbyagricultureis being abandoned in all sorts of ecosystemsaround the world as economics and lifestyleschange. In Old Fields, leading experts synthe-sizepastandcurrentworkontheseabandonedlands, providing an up-to-date perspective ontheir ecological dynamics. In chapter �, fromwhichthisexcerptisdrawn,KarenD.Hollre-viewsongoingdebatesinthesuccessionallitera-ture,andevaluatesthreeinterrelatedquestionsinthecontextoftropicaloldfields.
Figure 6.2: Factors affecting (boxes) different modes of regeneration (ellipses) of tropical old fields.
�1Chapter 6: Old Field Vegetation Succession in the Neotropics
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ent,giventhemanyotherfactorsthatmayinfluencetherateofrecovery.Asecondunderlying,large-scale,climaticgradientistemperature.Temperature,however,isgenerallycon-sideredalessimportantdrivingfactorintropicalfor-estscomparedtorainfall.Themaineffectoftempera-tureonrecoveryisinhigherelevationsystemssuchascloudforests,wheretheslowgrowthrateoftreescan increase the time of recovery (Ewel 1980). Ad-ditionally,Zarinetal.(�001)foundthatgrowingsea-sondegrees(growingseasonlength×growingseasontemperature)wasa significantpredictorofbiomassacrossnumerousoldfieldsintheBrazilianAmazon,anareaoflittletopographicvariation,suggestingthattemperatures may be an important predictor of re-coveryatlargerscales.Afinalimportantabioticgradientissoiltype.Muchofthetropicsarecoveredbyoxisolsandultisols,whichhave low nutrient levels and high acidity. Some ar-eashavemorefertile,volcanicsoils,suchasandisolsandinceptisols,althoughthesesoilscommonlyhavelowavailablephosphorus.Someauthors(Moranetal.�000;Zarinetal.�001)havenotedthatoverlargespa-tialscales,differencesinsoiltextureandfertilitymorestronglyaffecttherecoveryofbiomassthanpreviouslanduse(discussedlater).Forexample,Moranetal.(�000)studiedforestrecoveryacrossarangeoflanduses (pasture, swidden, mechanized agriculture) atfivelocationsinColombiaandBrazil.Hefoundthatinterregionalvariationsinbiomassandstandheightwere best explained by soil fertility, whereas withinsinglelocationspreviouslanduseexplainedmostofthevariation.Soilpatterningatsmallerscalescanalsoaffectspeciesdistributions.Forexample,HerreraandFinegan(199�)foundthatthedifferentabundancesoftwocommontreespecies,Vochysia ferrugineaandCordia alliodora, reflected differences in exchange-ableacidity,slope,andmagnesium.
Surrounding Landscape Mosaic
Gradientsofclimateandsoilprovidea templateonwhichvariousanthropogenicfactorsacttoinfluenceneotropicalforestrecovery.Aprimaryanthropogen-icfactoraffectingsuccessionintropicaloldfieldsisthemosaicofsurroundinglandcovertypes,suchasremnantforest,complexagroforests,shiftingcultiva-tion, pasture, or intensive agriculture (reviewed in
GuariguataandOstertag�001;Holl�00�;Chazdon�00�, �00�). Although swidden agriculture (shift-ingcultivation)isimportantalongsomeagriculturalfrontiers(FineganandNasi�00�),theintensityandscaleofagricultureinthetropicsisgenerallyincreas-ing. Therefore, the many regenerating sites embed-ded within agricultural landscapes are increasinglyisolatedfromsourcesofseedsforrecolonization.Many studies in secondary growth habitats in thetropics demonstrate that seed rain and seedling es-tablishment, particularly of large, animal-dispersedspecies,declinerapidlywithincreasingdistancefromtheforestedgebothinwetanddryforests(e.g.,AideandCavelier199�;Harvey�000;Zimmermanetal.�000;Mesquitaetal.�001).Thescaleoverwhichthisdeclineoccursrangesfromwithinafewmetersofthepastureedgeupto100meters.Needlesstosay,manyabandonedoldfieldsare>100metersfromtheforestedge,adistanceatwhichthereisgenerallyminimalseedrainunlessthereiswoodyvegetationtoattractseed dispersers. This isolation may be mediated byland use types, such as agroforestry, that facilitatemovementof someseeddisperserswithin theagri-culturalmatrix(FineganandNasi�00�;Harveyetal.�00�;Kupferetal.�00�).Giventhattheareaundersecondarysuccessionisincreasing,successionalfor-estsmaybetheprimarysourceofseedsofearlysuc-cessionalspeciesinmanyrecoveringareas(Fineganand Nasi �00�). Nonetheless, there have been fewstudies comparing seed rain or vegetation recoveryasafunctionofdifferentsurroundinglanduses.Thelackofseeddispersalintoabandonedoldfieldscanaffectboththerateofrecoveryaswellasthesuc-cessional trajectory, and a number of authors haverecorded lower numbers of individuals and speciesestablishing in old fields farther from forest (Mes-quitaetal.�001;Chinea�00�;Fergusonetal.�00�).For example, Hooper et al. (�00�) found that com-munity composition varied substantially with dis-tancefromtheforestedgeinabandonedpasturesinPanama.However,mostofthesepaststudiesontheeffectofdistance to forestedgeonvegetationcom-munitycompositionhavebeencarriedoutoverrela-tivelyshorttimeperiods(<�years)andlonger-termstudiesarecriticaltofurtheringourunderstandingofsuccessionaltrajectories.
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The surrounding landscape also has substantial ef-fects on the faunal communities, which may affectnotonlyseeddispersal,butothercommontropicalplant community mutualisms, such as pollinationandherbivory.Thereisgrowingevidencethatchang-esinmammalassemblagesduetohunting,isolation,or fragmentation (Dirzo and Miranda 1990; Chap-manandChapman199�)canbedetrimentaltotherecruitmentofmanyneotropicaltrees.Large-seededspeciesthatareanimaldispersedmaybeparticularlyatriskofdisappearingfromfragmentedareasduetolossofdispersers(CordeiroandHowe�00�).Inad-dition,disruptionof theseanimalcommunitiescancauseprofoundchangesinseedfate(DirzoandMi-randa1990),secondaryseeddispersal(Forget199�),and seedling recruitment (Benítez-Malvido 1998).Despite the likely impacts of the surrounding landusemosaiconseedpredationandseedlingherbivory,ithasreceivedmuchlessstudy(HollandLulow199�;DuncanandDuncan�000;Jonesetal.�00�)andisaripeareaforfutureresearchonvegetationdynamicsintropicaloldfields.
Excerpted from Old Fields edited by Viki A. Cramer and Richard J. Hobbs. Copyright © 2007 by Island Press. Excerpted by permission of Island Press. All rights reserved. No part of this excerpt may be repro-duced or reprinted without permission in writing from the publisher. Island Press grants permission to forward this unaltered electronic document to friends, colleagues, and other interested parties.
a guidE foR dESERt and dRyland REStoRation
A Guide for Desert and Dryland RestorationNew Hope for Arid Lands
DavidA.Bainbridge
Cloth,$100.00,ISBN1-��9��-9�8-�
Paper,$�0.00,ISBN1-��9��-9�9-�
�00�.�1�pages.8x10
Tables,figures,index
Contents
A User’s Guide ix
Preface xi
Acknowledgments xv
Chapter 1.Desertification:CrisisandOpportunity 1
Chapter 2.UnderstandingtheEcologyofAridLands 1�
Chapter 3.TheEconomicsandPsychologyofDesertification ��
Chapter 4.WhytheDesertCan’tHealItself:UnderstandingDisturbance ��
Chapter 5.RestorationApproachesandPlanning 90
Chapter 6.RestorationEquipmentandSupplies 11�
Chapter 7.ProjectManagement 1�1
Chapter 8.SoilSalvageandRestoration 1��
Chapter 9.SeedCollection,Storage,andManagement 1��
Chapter 10.ContainerPlantProductionandPlanting 190
Chapter 11.DirectSeeding �1�
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Chapter 12.WaterManagementandIrrigation ���
Chapter 13.RiparianRestoration ��8
Chapter 14.RestorationinUse ��8
Chapter 15.RestorationMonitoring �01
Chapter 16.TheChallengeAhead �1�
Appendix 1:PlantSamplingBackgroundandMethods ��9
Appendix 2:StayHealthy ���
Glossary ���
References ��9
AbouttheAuthor ���
Index ���
��Chapter 1 : Desertification: Crisis and Opportunity
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From chapter 1, “Desertification: Crisis and Opportunity”
The Task Ahead
Drylandrestorationisneededinalmosteveryplacehumans have been active past the gatherer–hunterstage (Bainbridge 198�b). Areas now considered tobedesert-likeinmanycaseswerecomplexandpro-ductiveecosystemsbutweregraduallyorquicklyde-stroyed by poor management. South-eastern Spain
providesanexcellentexampleofahuman-madedes-ert,anditisbutoneofmany(Latorreetal.�001).The semiarid and arid areas of the world make upabout��percentofthegloballandareaandaccountfor 1� percent of the world’s population. In 1980about ��0 million people suffered losses in incomeand quality of life from degraded drylands (Table1.�).Todaytheselandsaffectthedailylivesofmorethan8�0millionpeople,andeveryyearanother1–1.�millionhectaresarecompletelylosttoproductionthrough desertification (Dregne 198�; United Na-tionsEnvironmentProgramme�00�).Byaddressingthe underlying causes of dryland deterioration,un-derstandingthehistoryofabuseandchange,andap-plyingthebestrestorationtechniqueswecanbegintoreversethesechanges.Globallymore than�0percentof therangeland,�0percent of rainfed croplands, and �0 percent of ir-rigatedcroplandsareatriskforfurtherdegradation(Figure1.�).Pooruseoffragileresourceshaslimitedtheabilityofdrylandresidentstomakealiving,re-duced their quality of life, destroyed communities,ledtoconflictsover landandwater,reducedhealthandlifeexpectancy,andseverelyaffectednaturalsys-temsandbiodiversity(LeanandHinrichsen199�).Landdegradationinoneareaoftenaffectsotherar-easthroughincreasedflooding,reducedstreamflow,and dust and sand deposition. Recent studies haveevensuggestedalinkbetweendustfallresultingfromdesertification in Africa and coral reef dieback intheCaribbean.Thedustfromthegrowingdesertsin
About This Excerpt
Is there hope for reversing and repairing aridlands? Dryland degradation and desertifica-tionnowaffectalmostabillionpeoplearoundthe world. In A Guide for Desert and Dryland Restoration,DavidBainbridge,whohasworkedindesertsfortwenty-fiveyears,offerspractical,field-tested solutions to this critical problem.Writtenforrestorationpractitioners,landman-agers,ranchers,farmers,educators,landscapers,andforesters,thisbookismeanttobeusedinthefieldandonthegroundtoimprovelandandwatermanagement.Inthisexcerptfromchapter1,Bainbridgeoffersanoverviewoftheproblemofdesertificationandforecaststheelementsofeffectiverestorationefforts.
Table 1.2: Areas affected by severe or very severe desertification (percentage)
Cropland
Rangeland Rainfed Irrigated
Very Severe Severe Very Severe Severe Very Severe Severe
Africa 0.4 53.3 0.7 6.5 — 1.2
Asia 0.7 44.0 1.4 8.5 1.8 6.3
Europe 1.1 46.0 0.4 14.6 0.9 3.9
Australia 4.4 8.4 <0.1 1.0 1.1 7.0
North America 2.1 59.0 0.2 1.0 1.0 3.5
South America 3.9 47.2 0.6 2.6 0.7 3.7
�� A Guide for Desert and Dryland Restoration
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westernChinahascircledtheglobe,withlargelyun-knownaffectsonecosystemswherethedust,fungalspores,andnutrientsaredeposited.Restorationandimprovedmanagementof thesere-sourcesareessentialinreversingtheprocessofdeg-radationanddesertification.Restorationmayincludeawiderangeof interventions, fromsurfaceshapingtosoilamendments,tillageandweedremoval,seed-ing,planting, irrigation,andaftercare.Low-cost re-vegetation efforts can help restore productivity todegraded grazing lands. On severely damaged sitestheestablishmentofanyspeciesmaybedifficult,andeventhegrowthofweedsmaybeconsideredasuc-cess. Rehabilitation and reclamation are used to de-scribeeffortstoreturnsitestouseinstableconditionbutoftenwithintroducedspeciesandlesscomplexitythanarestorationproject.Ecologicalrestorationtriestorestoreecosystemfunction(howthingswork)andstructure (how things look) to match undisturbedreferencesites.Thiscanbeverydifficultbecauseourunderstanding of these dryland systems is limitedandtheenvironmentalvariabilityisveryhigh,char-acterizedbypulsesratherthansteadyprogresseveninundisturbedand“stable”conditions.
Restoration Efforts
Work on dryland restoration began in earnest inabout1980,althoughprojectsintheSouthwestwerestartedasearlyas1900andmanywereattemptedinthe19�0s(Griffiths1901;Coxetal.198�).Withouta solid scientific base and without controlled ex-perimentsandresearch,progresswaslimited.Manyflawedandinappropriateapproacheswereusedoverand over because managers were ignorant of what
otherpeoplehaddoneinearliertrials.Researchef-forts were also hampered by a very limited under-standingofaridandsemiaridecosystems(Hall�001).Mostresearchersandlandmanagershadcomefrommorehumidareaswherevegetationdidrecovernatu-rally,andfewstudiedthelessonsfromotherdrylandsaroundtheworld.Althoughrestorationisdesirableforbiological,eco-nomic,social,andaestheticreasons,itcanrarelybejustifiedwithcurrentincompleteeconomicaccount-ing practices. This has also hampered research andlimitedtrialsanddemonstrationstoshort-termstud-ies.Fundingforlong-termresearchhasbeenrareandsupportforintegratedresearchrarerstill.Whystudytheeffectsofspending$�,000anacreforapotentialgrazingreturnoflessthan$�0ayear?Restoration research also provides us with an oftenhumblingopportunitytotestandrefineourapplica-tion and understanding of ecological processes andtheories(Bradshaw199�b).Althoughtherootsofthescienceofrestorationecologycanbetracedbacktothelate1800sinEurope,AldoLeopoldandhisworkattheUniversityofWisconsinduringtheGreatDe-pressionlaidthefoundationforenvironmentalresto-rationinAmerica.Althoughsomeexcellentworkwasdoneonrecoveryafterdisturbanceinthe19�0sand1980s (Vasek et al. 19��; Lathrop 198�b; Prose andMetzger198�),moderninterestandcommitmenttoresearchandpublication improvedrapidlyafter theSocietyforEcologicalRestoration(SER)Internation-alhelditsfirstannualconferencein1989inOakland,California.Thisconferenceincludedafewpapersondrylandrestoration.In199�IledthefirstSERwork-shop on dryland restoration at Red Rock CanyonStateParkinCaliforniawithRayFransonandLaurieLippitt(Figure1.�).Thishands-ontrainingiscriticalinimprovingunderstandingandmanagement.Many other projects were started about this timethroughouttheSouthwest,andIhavelearnedmuchfromtheirsuccessesandfailures.Mycolleagues,staff,andstudentshavealsocontributedagreatdealtomyunderstanding.Thisresearchandtestinghaveledtoimprovedtechniquesandapproachesfordesertres-toration,butitwillneverbeeasy.Amultidisciplinaryapproachisverydesirableforres-torationwork.Ideallyateamwillbeabletoprovideinsight about not only the plants, soil microorgan-
Figure 1.6: World desertification map, with severity indicated by shading.
Desertification
��Chapter 1 : Desertification: Crisis and Opportunity
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isms,insects,animals,reptiles,andbirdsbutalsothecurrentandhistoricnationalandinternationaleventsthat have determined the economic incentives andpressures that influence land managers. Restorationbegins with a clear understanding of environmentalhistory,currentconditions,andthedecision-makingenvironment and leads through planning, funding,andimplementationtomaintenanceandmonitoring.Settingappropriaterestorationtargetsoftenisacriti-calissueandisdiscussedinmoredetailinChapter�.Current lawsoften require land tobe restoredonlytotheconditionitwasinbeforethelatestinsultandinjury.Thiscouldmeanrestoration toaliengrassesand weeds in much of the western United States.Others think, as I do, that restoration should con-siderconditionsbeforeovergrazingbegan,whenthelandwasmanagedbynativepeople.Thismaymeanbefore 1800 in California and before 1�00 in NewMexico.Wemustrememberthatthismeansareturntoadifferentmanagementscheme,notatimewhenthere was no human manipulation of the environ-ment.Mostof these landswereoccupiedandman-agedforthousandsofyears,oftensuccessfully,beforethearrivalof theEuropeans. Ifwewant togoback
beforehumaninterventioninlanduse,wewouldbeback��,000yearsormoreinCaliforniaandperhaps��0,000yearsinAustralia.ThenativepeopleofwhatisnowcalledsouthwesternNorthAmericawere intelligent,skilled,andknowl-edgeableappliedecologistswhoactivelymanagedtheland and shaped its ecosystems (Lawton and Bean19�8; Shipek 1990; Anderson 199�). Although theydid not have bulldozers, tractors, and transnationalseedcompanies theywere skilled in theuseof fire;kept animals; hunted some species very effectively;selected, transported, and planted seeds for annualand perennial crops; and transplanted trees andshrubs. A better knowledge of their managementpracticescanexplainmanybiologicalmysteries,anditwillalsohelp improveour landmanagementandprotectionof rareandendangeredspeciesandeco-systems(Figure1.8).
Restoration Is Possible
Successful restorationrequiresa systematic,holisticviewoftheinteractionsbetweenhumansandtheen-vironmentthroughtime.Themostappropriateresto-
Figure 1.7: The first SER desert restoration class, hosted by Red Rock Canyon State Park, California. Hands-on learning is best for restoration training.
�8 A Guide for Desert and Dryland Restoration
SER Restoration Reader
Figure 1.8: Lessons from the past: (a) Terraces and (b) reservoir at Mesa Verde, Colorado, demonstrate proven methods for soil and water conservation in arid lands.
A )
B )
�9Chapter 1 : Desertification: Crisis and Opportunity
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rationapproachforagivensitedependsonthetypeofdisturbance,thedegreeofdisturbance,thecausesof the disturbance, the available budget (both timeandlabor),andthegoalsandspeedofrecoveryde-sired.Theeffortshouldalwaysincludeconsiderationofecosystemstructureandfunction.Traditionallystructurehasoftenbeenfavored(howmanyplants,whatkinds)over function(water flowandretention,nutrientcycling),butrepairingfunc-tionusually ismore important.Likemanyothers, Ioriginally began with a focus on returning specificplants,butaftera fewyears itbecameclear thatre-storing function was more important. If ecosystemfunctionisrestoreditwillhastenrecoveryandensurethattheenvironmentcontinuestoimproveaftertherestorationteamleaves.Thecost for restorationcanrange froma fewhun-dreddollarsto$�0,000peracreormore.Asthein-vestmentincreasestherateofrecoverywillincrease,butevenlargeexpendituresarenoguaranteeofsuc-cess intheseextremeenvironments.Everythinghastobedonecorrectlyattherighttime,andwaterusu-allyhastobeprovidedforinitialestablishment.The cost of failing to restore damaged drylands ishigh,biologically,socially,andeconomically.Yetun-til recently thevalueof theecosystemservicespro-vided by nature has not been counted, and an eco-nomic justification for restoration was lacking. Thefunctionsoffloodcontrol,waterpurification,oxygenproduction,anddustcontroldomatter,andtheydohavevalue.WhenRobertDixoncompared thecostofabigfloodinTucsonwiththecostofdrylandres-toration,whichwouldhavelessenedorpreventedthe
flood,therestorationwouldhavecostless.Asnature’sservicesaremorecompletelyandclearlyvalued,res-torationwillbecomemorecommonasaneconomicinvestment.Itwillalwaysremainanimportantactiv-ityforbeauty,biodiversity,recreation,andqualityoflife.Restorationalsoprovidesinvaluableopportuni-tiestotestourtheoryandknowledgeabouthoweco-systemsfunction(Bradshaw199�b).Themagnitudeofthetaskgloballycanbecalculatedfromthevastareasoflandneedingtreatment.Amod-est restoration program to repair just 10 percent ofthedesertifiedrangelandsintheUnitedStatescouldcost$��billionayear,about1�percentof thecur-rentbudgetfortheDepartmentofDefense.Totreat10percentofthe�.�billionhectaresofdegradeddry-landsintheworldeachyearwouldcostabout$��0billion dollars, about � percent of the annual grossdomestic product of the United States. Sadly, thecountriesthatareworstaffectedareleastabletopay,withmanystrugglingtopayimmensedebtservicesonloansfromrichcountries.Inmanycasestheirto-talexternaldebtsaremorethanthreetimestheirto-talforeignexchangeearnings.Theongoingefforttorelievesomeofthispressureiscriticalbecausethesehighdebtservicerequirementsoftendriveresourcemismanagement.
Excerpted from A Guide for Desert and Dryland Restoration by David A. Bainbridge. Copyright © 2007 by Island Press. Excerpted by permission of Island Press. All rights reserved. No part of this excerpt may be repro-duced or reprinted without permission in writing from the publisher. Island Press grants permission to forward this unaltered electronic document to friends, colleagues, and other interested parties.
REStoRing thE pacific noRthwESt
Restoring the Pacific NorthwestThe Art and Science of Ecological Restoration in Cascadia
EditedbyDeanApostolandMarciaSinclair
ForewordbyEricHiggs
Cloth,$99.9�,ISBN1-��9��-0��-9
Paper,$�9.9�,ISBN1-��9��-0�8-�
�00�.�09pages.8x10
Tables,figures,index
Contents
Foreword xiiiEric Higgs
Preface xviiPeter Lavigne
Acknowledgments xix
Introduction xxiiiDean Apostol
PART I. The Big Picture 1
Chapter 1.NorthwestEnvironmentalGeographyandHistory �Dean Apostol
Chapter 2.EcologicalRestoration 11Dean Apostol
�1Chapter 17 : Traditional Ecological Knowledge and Restoration Practice
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PART II. Pacific Northwest Ecosystems 27
Chapter 3.BunchgrassPrairies �9Marcia Sinclair, Ed Alverson, Patrick Dunn, Peter Dunwiddie, and Elizabeth Gray
Case Study: YellowIslandRestorationovertheLongTerm ��
Case Study:WestEugeneWetlands ��
Case Study:GarryOakEcosystemRestorationinCanada �8
Case Study:FortLewisWildflowerExplosion �9
Chapter 4.OakWoodlandsandSavannas ��Paul E. Hosten, O. Eugene Hickman, Frank K. Lake, Frank A. Lang, and David Vesely
Case Study:ManagingCulturalandNaturalElementsoftheBaldHillsofRedwoodNationalandStateParks 8�
Case Study:FuelReductionandRestorationinOakWoodlandsoftheApplegateValley 8�
Case Study: EcologicalRestorationatBaldHill,Corvallis,Oregon 89
Chapter 5.Old-GrowthConiferForests 9�Jerry F. Franklin, Dean Rae Berg, Andrew B. Carey, and Richard A. Hardt
Case Study:BiologicalComplexityRestorationatFortLewis 11�
Case Study:UpperSiuslawLate-SuccessionalReserveRestorationPlan 11�
Case Study: MonteCarloThinning 11�
Chapter 6.RiparianWoodlands 1��Dean Apostol and Dean Rae Berg
Case Study:RiparianSilvicultureatKennedyFlats,VancouverIsland,BritishColumbia 1�0
Case Study:RiparianRestorationinPortland,Oregon 1��
Chapter 7.FreshwaterWetlands 1�0John van Staveren, Dale Groff, and Jennifer Goodridge
Case Study:KingCountyWetlandMitigationBank,Washington 1��
Case Study: MudSlough,Oregon 1��
Case Study:ClayStationWetlandMitigationBank 1�8
Chapter 8.TidalWetlands 1��Ralph J. Garono, Erin Thompson, and Fritzi Grevstad
Case Study:DeschutesRiverEstuaryandCapitolLakeRestorationStudy 18�
Case Study:ControlofInvasivePlantsinWillapaBay,Washington 18�
Case Study:HabitatMappingintheLowerColumbiaEstuary 18�
�� Restoring the Pacific Northwest
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Case Study:PadillaBayEstuarineResearchReserve 188
Case Study: NehalemBay 189
Case Study:TillamookBay 190
Case Study:SouthSloughNationalEstuarineResearchReserve 191
Chapter 9.PonderosaPineandInteriorForests 19�Stephen F. Arno and Carl E. Fiedler
Chapter 10.ShrubSteppe �1�Steven O. Link, William H. Mast, and Randal W. Hill
Case Study:HanfordPrototypeBarrier ��8
Case Study:ReducingUnnaturalFuelsintheShrubSteppe ��0
Case Study:RestorationofUplandHabitatsatColumbiaNationalWildlifeRefuge ���
Case Study:CanoeRidge ���
Chapter 11.Mountains ��1Regina M. Rochefort, Laurie L. Kurth, Tara W. Carolin, Jon L. Riedel, Robert R. Mierendorf, Kimberly Frappier, and David L. Steensen
Case Study:RestorationofaSmallImpact:ParadiseSocialTrail ��8
Case Study:SunriseCampground,Mt.RainierNationalPark ��0
Case Study:WhitebarkPineRestorationinGlacierNationalPark ��8
PART III. Crossing Boundaries 277
Chapter 12.UrbanNaturalAreas ��9Mark Griswold Wilson and Emily Roth
Case Study:TheColumbiaSlough’sCommunityPartnerships �8�
Case Study:ProtectingtheBackyardofBoise �8�
Case Study:TheSaanichApproachtoEnvironmentalProtectionandStewardship �89
Case Study: TheHighPointRedevelopmentProject �90
Case Study:BirdsasIndicatorsofHabitatQualityAlongUrbanStreams �9�
Chapter 13.StreamSystems �98Jack E. Williams and Gordon H. Reeves
Case Study:RestoringLargeWoodStructureinTenmileCreek �09
Case Study:RemovingaSmallIrrigationDaminBearCreek �1�
��Chapter 17 : Traditional Ecological Knowledge and Restoration Practice
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Chapter 14.LandscapeandWatershedScale �19Dean Apostol, Warren Warttig, Bob Carey, and Ben Perkowski
Case Study:BuildingaCultureofRestorationintheMattoleRiverWatershed ���
Case Study:Landscape-ScaleRestorationDesignintheLittleApplegateWatershed ���
Case Study:Landscape-ScaleRestorationintheSkagitRiverBasin ���
Case Study:KennedyFlatsWatershedRestoration ���
Chapter 15. RestoringWildlifePopulations ��1Bruce H. Campbell, Bob Altman, Edward E. Bangs, Doug W. Smith, Blair Csuti, David W. Hays, Frank Slavens, Kate Slavens, Cheryl Schultz, and Robert W. Butler
Case Study:RestoringPopulationsofCavity-NestingOak-AssociatedBirdSpecies ��8
Case Study:GrayWolves ��0
Case Study:RestorationoftheColumbiaBasinPygmyRabbit ���
Case Study:RestorationofWesternPondTurtles ���
Case Study:TheTeeter-TotterEffectofEagleRecoveryonGreatBlueHerons ���
Case Study:RestorationofButterfliesinNorthwestPrairies ���
Chapter 16.ManagingNorthwestInvasiveVegetation ���David F. Polster, Jonathan Soll, and Judith Myers
Case Study:RepeatedCuttingtoTameReedCanarygrass �8�
Case Study:EliminatingScotchBroom �8�
Case Study:BiologicalControl �89
Two Case StudiesonHerbicideUse �90
Chapter 17.TraditionalEcologicalKnowledgeandRestorationPractice �9�René Senos, Frank K. Lake, Nancy Turner, and Dennis Martinez
Case Study:TheKarukTribeofNorthernCaliforniaandLocalFireSafeCouncils—FuelReductionProjects,WildlandUrbanInterface,andFuelBreaks �0�
Case Study: LomakatsiRestorationProject,SouthernOregon �0�
Case Study:HuckleberryCropManagement �0�
Case Study:WildlifeCrossingDesignontheFlatheadIndianReservation �08
Case Study: PacificLampreyResearchandRestoration �10
Case Study:SalmonRestorationinthePacificNorthwest �1�
Case Study:PaleoecologyandSalishSeaRestoration �1�
�� Restoring the Pacific Northwest
SER Restoration Reader
Case Study:BacktotheFuture �1�
Case Study:RekindlingtheFireofCamasProduction �1�
Case Study:RestoringWapatoonShuswapLake �18
Conclusion:TheStatusandFutureofRestorationinthePacificNorthwest ���Dean Apostol and Marcia Sinclair
AbouttheContributors ��1
SupportersandPartners ���
Index ���
��Chapter 17 : Traditional Ecological Knowledge and Restoration Practice
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From chapter 17, “Traditional Ecological Knowl-edge and Restoration Practice,” by René Senos, Frank K. Lake, Nancy Turner, and Dennis Martinez
Key Concepts in TEK Restoration
Kincentricity
A key concept in the indigenous world view is kin-centricity , or a view of humans and nature as partofanextendedecologicalfamilythatsharesancestryandorigins(Salmón�000,Martinez199�).Thekinorrelativesincludeallthenaturalelementsofanecosys-tem;indigenouspeoplesometimesrefertothisinter-connectednessas“allmyrelations.”Kincentricityac-knowledgesthatahealthyenvironmentisachievableonlywhenhumansregardlifearoundthemaskin.Kinshipwithplantsandanimalsentails familial re-sponsibilities;ittellsuswhyweareonthisearthandwhatourecologicalroleornicheisvis-à-visourrela-tivesinthenaturalworld.Toputitanotherway,ittells us that we are a legitimate part of nature, thatwe have responsibilities within nature, and that inexercising those responsibilities we are as “ecologi-cal”or“natural”asanyotherspecies.Theindigenouslandethicholdsthatwecanhaveapositiverestora-tioneffectintheveryactofusingnaturalresources.Kincentric ecology entails direct interaction with
naturetopromoteenhancedecosystemandculturalfunctioning.Thisiswhatsustainablepracticesareallabout.Ourresponsibilityforparticipatinginthe“recreationoftheworld”(astribesonKlamathRiver innorth-westernCaliforniacallit)isneverfinished.PeriodicinterventionbyhumansinnaturehaslongbeenpartofecosystemdynamicsinthePacificNorthwest.Giv-enthemyriadecologicalcatastropheswenowface,theneedforactiverestorationwillonly increase.Therearenofinishedrestorationprojects.Naturehasself-healingpowers,buttheseengageonlyafteraspecificharmfuldisturbance(e.g.,adamorinvasivespecies)isremovedormodified.Humansalsocanlendahandby restoring missing species, modifying structure,and so forth.As theSERIPrimernotes, continuingmanagement is necessary to “guarantee the contin-uedwell-beingoftherestoredecosystemthereafter”(SocietyforEcologicalRestoration�00�:�).Pioneering Western ecologists and restorationistshavecometosimilarconclusionswithrespecttokin-centricity,startingwithAldoLeopold(19�9)andhisland community ethic, which posited that an indi-vidual is a member of a community of interdepen-dentpartsandthateachcitizenisethicallyboundtomaintaincooperativerelationswith thebioticcom-munity. Restorationist Stephen Packard discoveredthat recovering degraded Midwest landscapes re-quiredcorpsofdedicatedvolunteers torestoresev-eralthousandacresoftallgrassprairieandoaksavan-na(Stevens199�).Thisambitiousendeavorwasnotpossibleuntilpeople invested in therhomeplaces.Environment al philosopher Andrew Light (�00�)has explored the personal, moral, and environmentaldimensionsofmakingamendstoourkinthroughtheactofrestorationandconsidershowrestorationprovidesavenue forecologicalcitizenship.Kincen-tricityprovidesabasisforconsideringrestorationasaprocessofengagementwithnature,awaytosustainorrepairrelationswiththelivingworld.Indoingsowedevelopviablecultural,economic,andecologicalpracticesthatsupportandnurtureoursharedenvi-ronment.
Reference Systems
When addressing the needs of restoration today,whetheratthelandscape,habitat,orspecieslevel,it
About This Excerpt
The Pacific Northwest, stretching along thewest coast of North America from northernCalifornia throughBritishColumbia tosouth-eastAlaska, isa “hotspotofbogglingdiversityinrestorationprojects,”accordingtoEricHiggs,chairoftheboardofdirectorsoftheSocietyforEcologicalRestorationInternationalfrom�001to �00�. Restoring the Pacific Northwest bringstogetherfifty-sevenexpertsandpractitionerstoshowcasenineseminalhabitattypes,sixdistinctrestoration approaches, and more than threedozencasestudies.It isanessentialhandbookand encyclopedic overview for restorationistsand practitioners around the world. This ex-cerptfromchapter1�offerskeyconceptsintra-ditionalecologicalknowledge.
�� Restoring the Pacific Northwest
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is important to recognize indigenous peoples as aninfluence in shaping and maintaining the historicalconditionofmanydifferentecosystems.Inthissense,the effectofpast indigenousmanagementpracticesshouldbeconsideredpartofthereferenceecosystem,ormoregenerallyasprovidingasetofreferencepro-cessestoguidearestorationeffort.IntheNorthwest,reference conditions influenced by indigenous landuse practices of a pre-European era are the bench-mark.Anyreferenceconditionordesignof futuredesiredconditionsmustaccountforhumans’use andman-agementoftheenvironment.Thescaleandintensityofhumanuseandmanagementoftheenvironmentare important to successful ecocultural restorationandtoestablishingasustainablerelationshiptoplace.Our reference window is at least as large as 10,000years,or thepostglacialHoloceneperiod,withpar-ticularattentionpaidto the last�,000years,duringwhich a gradual cooling trend occurred that mostresembles present climatic and ecological condi-tions(Figure1�.�).The last10,000yearsalso is theperiodduringwhichhumanshaveexertedthemostinfluenceonNorthAmericanecosystems(EganandHowell�00�).Theuseofreferenceecosystemsinrestorationisnotwithout controversy. It can be expensive and time-consuming to use multiple disciplines and indirectproxylinesofethnographicandscientificevidenceto
establishareasonableprobabilityofaccuracyiniden-tifyingasiteataspecificpoint inhistory(seeEganandHowell�00�fortechnicalinformationregardingreconstructinghistoricalecosystems).Some restoration scientists and practitioners ques-tion the value of using historical baselines to guiderestoration.Notonlycanitbedifficulttoreconstructhistorical ecosystems because of severe changes insomeenvironments,butwhygobacktoanarbitrarypointinhistory?Whychoose,forexample,atimebe-foreEuropeancontactasthereference?Whynotjusttrytoimprovethefunctionofdegradedecosystems?Isn’tnatureconstantlychanging?However,TEKdoesnotadvocatethatwestopchangeandfreezeecosystemsinaparticulartimeframeorthatwerecreateasnapshotintime.Afterall,presentconditionsarealsoasnapshotintime.Whatwere-allyneedtodoisconnectthepastwiththepresentinordertorevealwhatkindoftrajectoryanecosystemmaybeonandthennudgethattrajectoryjustenoughtorestorekeyfunctions.Historyandfunction,then,areinseparable.BothHiggsandMartinezhavewrit-tenandspokenaboutbalancinghistoricalfidelityorauthenticitywithecologicalfunctionality.Insteadoffixingasnapshotintime,weneedtorerunamovingpicture,playedoutwithinboundariesdeterminedbyhistorical trends in disturbance regimes, includingthekinds,intensities,andfrequenciesofdisturbancewithwhichanecosystemhasevolved.For example, forest stand-level restoration projectsare subject to constraints imposed by the greaterlandscape scale. Although a reference ecosystemcan guide initial restoration efforts, these will bemodified by larger landscape considerations (e.g.,fragmentation, fire hazard, exotic species invasion,specieslosses),orevenlargerphenomenasuchascli-matechange.Anchoringthereferencemodelinrealhistorical time will help us to recover key featuresof ecosystem structure, composition, and processeswithinnaturalvariability ,witha look todesigningthefuturedesiredcondition.Buildingsoundreferencemodelsforecoculturalres-toration requires the best Western science and thebestofTEK,notoneortheother.Eachhasthepo-tential toreinforcetheotherandtocompensateforinherent methodological limitations by consideringhistoryandfunction,qualityandquantity,longterm
Figure 17.2: Ecosystem trajectory showing that humans represent an ecological force on the landscape.(From Lewis and Anderson 2002. Copyright © 2002 by the University of Oklahoma Press, Norman. Re-printed with permission. All rights reserved. )
��Chapter 17 : Traditional Ecological Knowledge and Restoration Practice
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and short term, culture and ecology, economy andenvironment.
Successional Theory and Disturbance
Traditional ecological knowledge complementscontemporaryknowledgeoffireecologybyprovid-ing information about historical and contemporaryapplications of fire by indigenous people, includingfire effects on wildlife and vegetation in differentenvironments. Indigenous knowledge of fire ecol-ogy includes but is not limited to variations in firefrequency,intensity,severity,andspecificityofareasburnedindifferentecosystemsorplantcommunitiesbyindigenouspeopleorbylightningignitions.TEKprovidesknowledgeaboutfireeffectsandecosystemresponses and about how physical and biologicalprocessessuchashydrologyandforestsuccessionre-spondtofireovertime(LewisandAnderson�00�).Integrating multiple knowledge systems to under-standtheeffectsoffireontheremainingpost-treat-mentvegetationor soilscan lead togreateraccom-plishmentofobjectives.Thinningandspringseasonpileburningmaybeintermediatestepsthathelppre-parethesiteforthereintroductionoffallseasonlow-intensity burns that emulate Indian fire (Williams�000). Ethnographic information and TEK may beinstrumentalateachtreatmentstep,especiallywhenoneisconsideringrestorationeffectsonwildlife,foodplants,ornontimber forestproducts, resources thathold high social and ecological value to local com-munities(Anderson�001).Restoring and maintaining biocultural diversity ofthe landscape through integrated restoration plan-ninginvolvesaninterdisciplinaryaswellasamulti-culturalapproach.Fuelreductionprojectsthatincor-porateIndianfirewillhavehigherlevelsofsuccessinrestoringandmaintainingbiodiversity,whichinturnwillsupportculturaldiversityandlocalcommu-nities.Thispremisemayholdtrueespeciallywithna-tiveculturesthathistoricallyandcurrentlyrelyonfireand fire-dependent landscapes for their sustenanceandculturalsurvival(Boyd1999).Acommunityfor-estryapproachcanhelplocalcommunitiescopewithlikely future changes caused by climate change andintensifieddemandsofnaturalresources.
Defining Scale
Issues of ecological and social scale are importantconsiderations in restoration work. Any restorationprogram directed toward a given geographic areamustcarefullydefinethescaleatwhichitwilloper-ate.Forexample,willprojectsfocusonasinglespe-ciesorpopulation,aparticularhabitat,oranentirewatershed?Willrestorationengagethecollaborationofanindividual,acommunity,oranationalorgani-zationorinstitution?Indigenous ways of understanding and relating totheenvironmentprovideusefulmodels for framingrestorationeffortsattheappropriatescale.IncoastalPacific Northwest environs, individual families tra-ditionallywereresponsible foraparticularresourcebaseataspecificlocation(e.g.,shellfishbeds).Villag-eswereorganizedaroundspecificplacesalongstreamreaches,andanaffiliatedtribalgroup(distinguishedby common linguistics) managed a given bioregion(J.James,personalcommunication,�001).Appropri-
Figure 17.3.
Scale of potential management effects. (From Lewis and Ander son 2002. Copyright © 2002 by the University of Oklahoma Press, Norman. Reprinted with permission. All rights reserved.)
�8 Restoring the Pacific Northwest
SER Restoration Reader
atetechnologiesandresourcemanagementpracticeswereritualizedtomaintainhealthyfunctioningofthesystematallsocialandecologicalscales.Definingthescaleofoperationprovidescontextforour individual actions linking with others’ actionsacross or up in scale. TEK provides an operationalframework that addresses the integration of thevarious ecological and social scales, situated withintemporalscales(Figure1�.�;Berkesetal.�000).Theperspectiveofscalecanalsobereflectiveinthatthestrengths and weaknesses of TEK and Western sci-ence are evaluated in the context of the restorationprogramorprojectsbeingplanned,implemented,ormonitored.
Excerpted from Restoring the Pacific Northwest by Dean Apostol and Marcia Sinclair. Copyright © 2006 by Island Press. Excerpted by permis-sion of Island Press. All rights reserved. No part of the excerpt may be reproduced or reprinted without permission in writing from the publisher.
thE tallgRaSS REStoRaation handbook
The Tallgrass Restoration HandbookFor Prairies, Savannas, and Woodlands
EditedbyStephenPackardandCorneliaF.Mutel
ForewordbyWilliamR.JordanIII
Cloth,$��.00,ISBN9�8-1-��9-���19-�
Paper,$��.00,ISBN1-�9���-0��-�
�00�.�0�pages.�x9
Index,appendix
Contents
List of Illustrations xi
List of Tables xii
Forewordby William R. Jordan III xiii
Preface to the 2005 Edition,by Cornelia F. Mutel and Stephen Packard xix
Perspective,by Stephen Packard and Cornelia F. Mutel xxv
Acknowledgments xxxv
Part I. Introduction
Chapter 1.OrchardsofOakandaSeaofGrass �Virginia M. Kline
Chapter 2.PrairieUnderground ��R. Michael Miller
�0 The Tallgrass Restoration Handbook
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Part II. Goals and Plans
Chapter 3.PlanningaRestoration �1 Virginia M. Kline
Chapter 4.RestorationOptions �� Stephen Packard
Chapter 5.RestoringRemnants ��Stephen Packard and Laurel M. Ross
Chapter 6.RestoringPopulationsofRarePlants 89James A. Reinartz
Part III. Seeds and Planting
Chapter 7.ObtainingandProcessingSeeds 99Steven I. Apfelbaum, Brian J. Bader, Fred Faessler, David Mahler
Chapter 8.TipsforGatheringIndividualSpecies 1��Richard R. Clinebell II
Chapter 9.DesigningSeedMixes 1��Neil Diboll
Chapter 10.SeedTreatmentandPropagationMethods 1�1James E. Steffen
Chapter 11.Interseeding 1��Stephen Packard
Chapter 12.PlowingandSeeding 19�John P. Morgan
Chapter 13.Hand-PlantedPrairies �1�Peter Schramm
Part IV. Management and Monitoring
Chapter 14.ConductingBurns ���Wayne R. Pauly
Chapter 15.SummerFires ���Roger C. Anderson
Chapter 16.ControllingInvasivePlants ��1Mary Kay Solecki
Chapter 17.MonitoringVegetation ��9Linda A. Masters
�1Chapter 1: Orchards of Oak and a Sea of Grass
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Part V. Protecting, Restoring, and Monitoring Animals
Chapter 18.Insects �0�Douglas J. Taron
Chapter 19. AmphibiansandReptiles �19Kenneth S. Mierzwa
Chapter 20.Birds ���Victoria J. Byre
Chapter 21.Bison ��9Allen A. Steuter
Appendixes
A.VascularPlantsofMidwesternTallgrassPrairies ��1Douglas Ladd
B.TerrestrialVertebratesofTallgrassPrairies �01Stanley A. Temple
C.Cross-ReferencesforPlantNames �1�
D.PublicationsonNaturalCommunitiesoftheTallgrassRegion ���
E.SourcesofSeedsandEquipment ���
F.RestorationContacts ���
Contributors ���
Index ��1
�� The Tallgrass Restoration Handbook
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From chapter 1, “Orchards of Oak and a Sea of Grass,” by Virginia M. Kline
The Tallgrass Prairie
What Is a Prairie?
Frenchexplorerscalleditprairie,takenfromaFrenchwordmeaning“meadow,”andearlysettlersadoptedthatnameforthisunfamiliarNewWorldgrassland,for which there seemed to be no appropriate wordinEnglish.Thosewhoexperiencedtheprairiefirst-handhadnoneedforaprecisedefinitionoftheterm;thatwouldcomemuchlater,afterafledglingscienceacquireditsownnewname:ecology.JohnT.Curtis,thefirstecologistattheUniversityofWisconsin,un-dertookwithhisstudentsthetaskofdelineatingandcharacterizingeachofthemajorbioticcommunitiesofWisconsin.Basedontheirextensivefieldstudies,Curtis’sbookThe Vegetation of Wisconsinwaspub-lishedin19�9.InitCurtisdefinedaprairieasanopencommunity,dominatedbygrass,andhavinglessthanonetreeperacre.Insettingthis limit,hecautionedthat thiswasanarbitrarydistinction for theconve-nienceofthosestudyingacontinuumofvegetation.Natureseldomdrawslines;onecommunityislikelytoblendintothenext.
Plants of the Prairie Community
Prairiesarerichinspecies,andthegrasses,compos-ites,andlegumesareespeciallywellrepresented.(SeeappendixAfora listingof tallgrassprairievascularplants.)Theparticulargroupof speciespresentde-pends on geographic location, since some species’rangesarelimitedtocertainareas withintheprairieregion;italsodependsonlocaltopographyandsoil.Prairies near the northern limits of the prairie re-giondifferincompositionfromthosefarthersouth,while within the same geographic area, prairies onhigh rockyhill slopes, sand terraces,deep silt loamsoils, and poorly drained lowlands also differ fromone another. In Wisconsin, characteristic grasses ofthedrierprairiesincludelittlebluestem,prairiedrop-seed,andside-oatsgrama.Siteswithdeepsilt loamsoilsaredominatedbybigbluestemandIndiangrass,while wetter sites have blue joint grass and prairiecordgrass.(SeeFigure1.1.)Disturbanceandfirehis-toryinfluencecompositionaswell;forexample,somespeciesrequiresoildisturbance,suchasthatprovidedbybisonwallowsoranimalburrows, toget started,andsomespeciesdobestwhenfiresarefrequentoroccurataparticularseason.Prairie plants grow close together, sharing availableresourcesintimeandspace.Somespeciesflowerear-ly in theseason, some inmidsummer, some in fall.Thusnotallthespecieshavetheirmostrapidgrowthphasesatthesametime;insteadtheytaketurns.Earlygrowerstendtobeshort,andheighttendstoincreaseoverthegrowingseason,culminatinginthetallgrass-esinearlyfall.However,somespeciesthatbloomlat-erthanthetallgrasses,includinggoldenrods,asters,andgentians,areshorterthanthegrasses,takingad-vantageoftheincreasedlightlevelsasthegrassleavesturnfallcolor.Beneaththesurface,rootsofdifferentshapes,sizesanddepthsdividethespace.
Adaptations of the Plants
Eachspeciesisadaptedtotheextremetemperatures,drought,wind,highlightintensity,fire,andgrazingthatarepartoftheprairieplant’senvironment.Someofthemorphologicaladaptationseasilyobservedontheprairie includefinelydividedornarrowverticalleavestopreventoverheatingbythesunandofferlessresistance to the wind, and leathery or waxy leaves
About This Excerpt
In the 19�0s, researchers at the University ofWisconsin-Madison Arboretum launched ex-perimentsaimedatlearninghowprairieswork,andthefieldofecologicalrestorationwasborn.The Tallgrass Restoration Handbook offers theexcitement and perspective of the trial-and-error, hands-on work of prairie restoration.Written by practitioners for practitioners, thisis a practical manual of the art and science ofprairie,savanna,andoakwoodlandrestoration.Inthisexcerpt,VirginiaKlineintroducesustothelivingcommunitythatmakesupthis“seaofgrassandorchardsofoak.”
��Chapter 1: Orchards of Oak and a Sea of Grass
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Figure 1.1: Prairie grasses.
(Note: There are as yet no popular guides to the identification of most prai-rie or woodland grasses and sedges. Yet these plants are crucial to restora-tion. The best way to learn them is to master the technical keys and to find local botanists who can coach you. The drawings and captions here will introduce a few of the most widespread species.)
a. Little bluestem (Schizachyrium scoparium): Seed heads throughout top half of the stems. Leaves folded (v-shaped) in bud. Base of stem very flat. Mesic to dry soil. Thigh high.
b. June grass (Koeleria macrantha): Long, compact, erect seed heads. Dry, often sandy soil. Shin high.
c. Big bluestem (Andropogon gerardii): “Turkey-foot” seed heads. Stems often multicolored (with blue, purple, red, green, yellow, and orange). Base of stem roundish. Leaves rolled in bud. Mesic soil. Head high.
d. Indian grass (Sorghastrum nutans): Seed head featherlike. Distinctive auricles (lobes that hug stem at base of leaf ). Mesic soil. Head high.
e. Porcupine grass (Stipa spartea): Needle-sharp seeds measure five to eight inches long. Dry soil. Waist high.
f. Blue joint grass (Calamagrostis canadensis): Wispy seed heads on three- to four-foot stems. Papery ligule around stem at base of leaf. Forms solid stands in wetlands; spreads by runners. Waist high.
g. Switch grass (Panicum virgatum): Open seed heads. Hairy where leaf meets stem. Wet-mesic soil. Chest high.
h. Canada wild rye (Elymus canadensis): Plant is pale blue-green at flow-ering time. Nodding heads of bristly seeds, which spread and recurve as they dry. Wet-mesic soil and woods edges. Waist to chest high.
i. Prairie dropseed (Sporobolus heterolepis): Very narrow leaves in dense clumps. Spherical seeds in open heads that rise well above leaves. Strong scent of buttered popcorn or hot wax. Mesic to dry soil. Seed heads waist high.
j. Prairie cord grass (Spartina pectinata): Coarse, rough-edged leaves tapering to very fine tips. Rows of brushlike seed heads. Wet soil. Over head high.
to reduce water loss. Unseen are the extensive rootsystems that make up two-thirds of the total plantbiomass—anadaptationthathelpsmaintainafavor-able water balance and allows rapid regrowth afterfireorgrazing.Budslocatedatorbelowthegroundsurfaceareimportantforresprouting,asistheability,ingrasses,toregrowfromnodeslowontheplant.Althoughweoftenconsiderwindandhighlightlev-els as factors that plants must withstand, wind andlight are important resources as well. Many prairiespecies take advantage of wind for pollen and seeddispersal.Manyhavea largeamountof leaf surface(eventhoughindividualleavesmaybesmall)totakeadvantageofthehighlightintensity,therebyincreas-ing productivity. Many of the plants, including thewarm-seasongrasses,carryoutphotosynthesisusing
adistinctivechemicalpathwaythat isadvantageousunderthehotanddryconditionsfrequentlyencoun-teredinprairies.ThisC�pathway(sonamedbecausethefirstproductformedisa four-carbonmolecule)allowsahighrateofphotosynthesisathightempera-turesandahigherefficiencyofwateruse.Tallgrassprairies are among the most productive vegetationtypesintheworld.
Fire
Fire is an important process in prairies, where it ispartofapositivefeedbacksystem,thegrowthofprai-riegrassprovidingexcellent fuel for fireandfire inturn stimulating the growth of prairie grass. Light-ningcanigniteaprairiefire,butduringthecenturies
�� The Tallgrass Restoration Handbook
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preceding European settlement, fires set by NativeAmericansweremuchmore important.Thesepeo-pleusedfireforavarietyofreasons,whichcanper-hapsbesummarizedasmanagingtheirhabitat.Theyburnedfrequently,possiblyasoftenaseveryyear.Where the climate is suitable for trees and shrubs,fire is critical to prevent woody invasion of prairie.Fireplayedamajorroleinmaintainingthemosaicofprairie, oak savanna, and oak forest that character-izedtheeasternboundaryoftheprairie.Firealsoin-creasesthevigorofmanyprairiespecies,andtheyearofaburnislikelytobeassociatedwithtallerplants,especially the grasses, and a greater abundance offlowers.Thestimulationisduetoremovalofthein-sulating litter of grass stems and leaves by the fire,whichallowsthesoiltowarmupearlierinthespringandthusincreasesthelengthofthegrowingseason.Todaymanagersofprairiesoftenusecarefullytimedburnstohelpcontrolunwantedexoticweedsaswell.
Excerpted from The Tallgrass Restoration Handbook by Stephen Packard and Cornelia F. Mutel. Copyright © 2005 by Island Press. Excerpted by permission of Island Press. All rights reserved. No part of this excerpt may be reproduced or reprinted without permission in writing from the publisher. Island Press grants permission to forward this unaltered electronic document to friends, colleagues, and other interested parties.
gREat baSin RipaRian EcoSyStEmS
Great Basin Riparian EcosystemsEcology, Management, and Restoration
EditedbyJeanneC.ChambersandJerryR.Miller
ForewordbyJamesA.MacMahon
Cloth,$�0.00,ISBN1-��9��-98�-�
Paper,$��.00,ISBN1-��9��-98�-�
�00�.��0pages.�x9
Tables,figures,index
Contents
Foreword ixJames A. MacMahon
Preface xiii
Chapter 1.RestoringandMaintainingSustainableRiparianEcosystems:TheGreatBasinEcosystemManagementProjectJeanne C. Chambers and Jerry R. Miller 1
Chapter 2. ClimateChangeandAssociatedVegetationDynamicsduringtheHolocene:ThePaleoecologicalRecord ��Robin J. Tausch, Cheryl L. Nowak, and Scott A. Mensing
Chapter 3.FluvialGeomorphicResponsestoHoloceneClimateChange �9Jerry R. Miller, Kyle House, Dru Germanoski, Robin J. Tausch, and Jeanne C. Chambers
Chapter 4.BasinSensitivitytoChannelIncisioninResponsetoNaturalandAnthropogenicDisturbance 88Dru Germanoski and Jerry R. Miller
�� Great Basin Riparian Ecosystems
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Chapter 5.GeomorphicandHydrologicControlsonSurfaceandSubsurfaceFlowRegimesinRiparianMeadowEcosystems 1��David G. Jewett, Mark L. Lord, Jerry R. Miller, and Jeanne C. Chambers
Chapter 6.EffectsofNaturalandAnthropogenicDisturbancesonWaterQuality 1��Michael C. Amacher, Janice Kotuby-Amacher, and Paul R. Grossl
Chapter 7.EffectsofGeomorphicProcessesandHydrologicRegimesonRiparianVegetation 19�Jeanne C. Chambers, Robin J. Tausch, John L. Korfmacher, Dru Germanoski, Jerry R. Miller, and David G. Jewett
Chapter 8.Explanation,Prediction,andMaintenanceofNativeSpeciesRichnessandComposition ���Erica Fleishman, Jason B. Dunham, Dennis D. Murphy, and Peter F. Brussard
Chapter 9.Process-BasedApproachesforManagingandRestoringRiparianEcosystems ��1Jeanne C. Chambers, Jerry R. Miller, Dru Germanoski, and Dave A. Weixelman
AbouttheEditorsandAuthors �9�
Index �99
��Chapter 9: Process-Based Approaches for Managing and Restoring Riparian Ecosystems
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From chapter 9, “Process-Based Approaches for Managing and Restoring Riparian Ecosystems,” by Jeanne C. Chambers, Jerry R. Miller, Dru Germanoski, and Dave A. Weixelman
Processes Structuring Great Basin Riparian Areas
The processes currently structuring riparian areasinthecentralGreatBasinarestronglyinfluencedbypast climates.Thepaleoecological records collectedaspartoftheEMProject,aswellaspreviousinvesti-gations,indicatethatamajordroughtoccurredintheregionfromapproximately��00to1�00YBP(Milleretal.�001;Chapter�).Duringthisdrought,mostoftheavailablesedimentswerestrippedfromthehill-slopesanddepositedonthevalleyfloorsandonside-valley alluvial fans (Chapter �). As a consequenceof this hillslope erosion, streams are now sedimentlimitedandhaveanaturaltendencytoincise.Infact,geomorphicdataindicatethatoverthepasttwothou-sandyears,thedominantresponseofthestreamstodisturbancehasbeenincision.Themostrecentepi-sodeofincisionbeganabout�00to�00YBP,whichpredates Anglo-American settlement of the area inthe18�0s.The tendency of a stream to incise depends on thesensitivityof thewatershedtobothnaturalandan-
thropogenic disturbance. Analysis of central GreatBasin watersheds indicate that stream incision isclosely related to watershed characteristics, includ-inggeology,size,andmorphology,andtovalleyseg-ment attributes like gradient, width, and substratesize(Chapter�).Inthesesemiaridecosystemswhereprecipitationand,thus,streamflowishighlyvariablebothbetweenandwithinyears,mostincisionoccursduring episodic, high-flow events. Since the initia-tionoftheEMProjectin199�,high-floweventsca-pableofproducingsignificantincisionhaveoccurredin199�and1998(Chambersetal.1998;Germanoskiet al. �001). Watersheds that are highly sensitive todisturbancerespondtomore-frequent,lower-magni-tuderunoffeventsthanwatershedsthatarelesssen-sitivetodisturbance,Thecombinedgeomorphicandhydrologic characteristics of the watersheds deter-minethecompositionandpatternofriparianvegeta-tionatwatershed-tovalley-segmentscales(chapter�).Thus,watershedattributesthatcharacterizebasinsensitivity to disturbance also have good predictivevalueforvegetationtypesandassociations.A number of the watersheds are characterized byprominent side-valley alluvial fans that influenceboth stream and riparian ecosystems. The fansreached their maximum extent during the droughtthatoccurredfromabout��00to1�99YPB(Milleretal.�001;Chapter�).Watershedswithwell-devel-oped fans often are characterized by stepped-valleyprofilesand,consequently,ripariancorridorsthatex-hibitabruptchangesinlocalgeomorphicandhydro-logicattributes.Becauseof the relationshipsamonggeomorphiccharacteristics,hydrologicregimes,andriparianvegetation,thefansalsoinfluenceecosystempatterns within the riparian corridors (Korfmacher�001;Chapters�and�).Manyofthefanscurrentlyserveas localbase-levelcontrolsthatdeterminetherateandmagnitudeofupstreamincision.Riparian ecosystems located immediately upstreamof alluvial fans often are at risk of stream incisionthroughthefandeposits.Manyofthefanshavemul-tipleknickpoints(ashort,oversteepenedsegmentofthelongitudinalprofileofthechannel)andaresub-jecttostreamincisionduetohighshearstressasso-ciated with knickzone migration during high-flowevents. Similarly, ecosystems located in watershedswith pseudostable channels can be degraded dur-ing catastrophic incision via groundwater sapping.
About This Excerpt
“Great Basin Riparian Ecosystems is not justabouttheecologyandrestorationofGreatBa-sinriparianareas,butalsothegeomorphologyandhydrologyoftheassociateduplands….Themost important lesson in these pages is thatrestorationists cannotescapehistory.Thegeo-morphichistoryiscriticaltounderstandingtherolesofhumans, livestock,andclimatechangeinstreamchannelincision,andrestoringtopre-settlementconditionsmayactuallyresultinanunstable state in a nonequilibrium landscape.Thelessonsrecountedherehavebroadimplica-tionsforothersystems.”
—EdithB.Allen,formereditorof Restoration Ecology
�8 Great Basin Riparian Ecosystems
SER Restoration Reader
Becausethestreamchannelservesasagroundwaterdischargepoint,itrepresentsthebaseleveltowhichthehydraulicgradientofthegroundwatersystemisadjusted. Stream incision lowers this base level forgroundwaterdischarge,resultingindeclinesinwatertablelevelsandsubsequentchangesinthecomposi-tionandstructureofriparianvegetation(Castellietal.�000;WrightandChambers�00�).Meadowcom-plexesarepresentlytheecosystemsmostsusceptibleto degradation not only because they are often lo-catedupstreamofalluvialfans,butalsobecausetheyaresubjecttoprocessessuchasgroundwatersapping(Chapter�).The rate and magnitude of stream incision in cen-tralGreatBasinwatershedshavebeen increasedbyanthropogenic disturbances. Because most of thestreamshavebeenpronetoincisionforthepasttwothousand years, separating changes attributable toongoingstreamincisionfromthoseassociatedwithanthropogenicdisturbancecanbeexceedinglycom-plex (Chapter �). In the cases of roads, diversions,andlivestockorrecreationaltrails,thepointofinitia-tionofstreamincisionoftencanbeidentifiedandthelocaleffectsofthedisturbanceonthestreamrecon-structed.Themostdirectevidencethatanthropogen-icdisturbancehasinfluencedstreamincisioninthecentralGreatBasinisderivedfromongoingstudiesontheeffectsofroadsonriparianareas.Increasingly,roadsare identifiedasmajor causesof stream inci-sionandriparianareadegradationacrosstheUnitedStates(USDAForestService199�;FormanandDe-blinger �000; Trombulak and Frissel �000). In thecentralGreatBasin,severalcausesof“roadcaptures”have been documented and many others observedwherestreamshavebeendivertedontoroadsurfacesduringhigh flows(Lahde�00�).Thisdiversionhasresulted in increasedshearstressandstreampowerand,ultimately,streamincision(Lahde�00�).Onceinitiated,streamincisionoftencontinuestooccurasaresultofknickpointmigration.Assigningcauseandeffecttomorediffuseanthropo-genic disturbances such as overgrazing by livestockismoredifficult.Ingeneral,overgrazingbylivestockcan negatively affect stream bank and channel sta-bility, and localized changes in stream morphologyoftenhavebeenassociatedwithovergrazingbylive-stock in the western United States (see reviews inTrimbleandMendel199�;Belskyetal.1999).How-
ever,datathatclearlydemonstratetherelationship(s)betweenregionalstreamincisionandovergrazingbylivestockhavenotbeencollectedforthecentralGreatBasin.Inreality,itmayneverbepossibletopreciselydistinguish the amount of channel incision causedby climate change from that due to anthropogenicdisturbance. From a restoration and managementstandpoint,itisimportanttorecognizethatbecauseparticulartypesofstreamsarepronetoincision,theyhavegreatersensitivitytobothnaturalandanthropo-genicdisturbances.Anthropogenicdisturbanceshaveeffectsonthecen-tral Great Basin riparian ecosystems that are unre-latedtostreamincision.Insemiaridrangelands,likethoseinthewesternUnitedStates,thegeneraldegra-dationofriparianareashasbeenattributedprimarilytoovergrazingbylivestock(seereviewsinKauffmanand Krueger 198�; Clary and Webster 1989; Skov-lin 198�; Fleischner 199�; Ohmart 199�; Belsky etal.1999).Livestockgrazinginfluencesriparianeco-systemsby(1)removingherbage,whichallowssoiltemperaturestoriseandresultsinincreasedevapora-tion;(�)damagingplantsduetorubbing,trampling,grazing,orbrowsing;(�)alteringnutrientdynamicsbydepositingnitrogeninexcreta fromanimalsandremoving foliage; and (�) compacting soil, whichincreases runoff and decreases water availability toplants.ResearchconductedonGreatBasinmeadowecosystems (Weixelman et al. 199�; Chapter �) andelsewhereshowsthattheseeffectscancausechangeinplantphysiology,populationdynamics,andcom-munity attributes such as cover, biomass, composi-tion,andstructure.Inaddition,overgrazingbylive-stockcanresultinlocaldecreasesinwaterqualityasaresultofincreasedsedimentfromroaddamageandroadcrossings(M.Amacher,unpublisheddata).Dis-turbancesdue to recreation, suchascampsites, andvehicleandfoottraffic,haveincreasinglywidespreadeffectsbuthavebeenpoorlydocumented.Thecumulativeeffectsofclimaticperturbationandanthropogenic disturbance in the central Great Ba-sinhavemultipleconsequencesforstreamsandtheirassociatedriparianecosystems.Therehavebeenma-jor changes in channelpatternand formandmanystreams have been isolated from their floodplains(Chapters�and�).Surfacewaterandgroundwaterin-teractionshavebeenaltered(Germanoskietal.�001;Chapter�),anddeclinesinwatertableshavecaused
�9Chapter 9: Process-Based Approaches for Managing and Restoring Riparian Ecosystems
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changesinplantspeciescompositionandvegetationstructure (Wright and Chambers �00�; Chapter �).Overgrazing by livestock and other anthropogenicdisturbances have caused additional degradation ofthese ecosystems. The net effects of these changeshavebeenadecreaseintherealextentofripariancor-ridorsandareductioninhabitatquantityandqualityforbothaquaticandterrestrialanimals.
Conceptual Basis for Management and Restoration
Theimportanceofdevelopingaconceptualbasisformanagingandrestoringdegradedecosystemsisgain-ing increasing recognition (Allen et al. 199�; Wil-liamsetal.199�;Whisenant1999;NationalResearchCouncil�00�).FordegradedriparianecosystemslikethoseintheGreatBasin,suchaconceptualbasismustconsiderboththetypeandcharacteristicsofdegra-dation,andtherecoverypotentialasdeterminedbytheunderlyingphysicalandbioticprocesses.InthecentralGreatBasinmanyofthestreamsand,consequently,riparianecosystemsarecurrentlyinanonequilibriumstate.Becauseofthedroughtthatoc-curredbetween��00and1�00YBPandtheerosionofavailablehillslopesediments,thestreamsaresedi-mentlimitedandexhibitatendencytoincise.Someofthestreamshaveadjustedtothenewsetofgeomor-phic conditions, in other words, they have reachedtheirmaximumdepthofincisionunderthecurrentsediment and hydrologic regime. Others are stilladjustingandwillcontinuetoincisebecauseofhet-erogeneouschannelprofilesandthelackofhillslopesediments. Due to the resulting changes in streamprocessesandsurfaceandgroundwaterrelations,ri-parianecosystemshavecrossed thresholds.Forourpurposes,thresholdcrossingsoccurwhenthesystemdoesnotreturntotheoriginalstatefollowingdistur-bance (Ritter et al. 1999). Threshold crossings canbedefinedbasedonthe limitsofnaturalvariabilitywithinsystems.Forstreamsandriparianecosystemsthathavecrossedgeomorphicandhydrologicthresh-
olds, returning the systemtoapredisturbance stateis an unrealistic goal. Thus, it is necessary to baseconceptsofsustainabilityandapproachestomanage-mentoncurrent,andnothistoric,streamprocessesandriparianecosystemconditions.AsoutlinedinChapter1,thegoalofrestorationandmanagement activities in the central Great Basin issustainablestreamandriparianecosystems.Sustain-ableecosystems,overthenormalcycleofdisturbanceevents,retaincharacteristicprocessesincludingratesand magnitudes of geomorphic activity, hydrologicflux and storage, biogeochemical cycling and stor-age, and biological activity and production (modi-fied from Chapin et al. 199� and Christensen et al.199�). Sustainable stream and riparian ecosystemsalso exhibit physical, chemical, and biological link-agesamongtheirgeomorphic,hydrologic,andbioticcomponents(Gregoryetal.1991).Thus,forthepur-posesofthisvolume,managingandrestoringripar-ianareasisdefinedasreestablishingormaintainingsustainable fluvial systems and riparian ecosystemsthatexhibitbothcharacteristicprocessesandrelatedbiological,chemical,andphysicallinkagesamongsys-temcomponents(modifiedfromNationalResearchCouncil199�).Inherentinthisdefinitionistheideathat sustainable ecosystems provide important eco-systemservices.InthecentralGreatBasin,ecosystemservicesfromriparianareasincludeanadequatesup-plyofhigh-qualitywater,habitatforadiversearrayofaquaticandterrestrialorganisms,forageandbrowsefornativeherbivoresandlivestock,andrecreationalopportunities.
Excerpted from Great Basin Riparian Ecosystems by Jeanne C. Cham-bers and Jerry R. Miller. Copyright © 2004 by Island Press. Excerpted by permission of Island Press. All rights reserved. No part of this excerpt may be reproduced or reprinted without permission in writing from the publisher. Island Press grants permission to forward this unaltered electronic document to friends, colleagues, and other interested parties.
SouthwEStERn pondERoSa pinE foREStS
Ecological Restoration of Southwestern Ponderosa Pine Forests
EditedbyPeterFriederici
ForewordbyGaryPaulNabhan
Cloth,$�0.00,ISBN1-��9��-���-1
Paper,$��.00,ISBN1-��9��-���-X
�00�.�8�pages.�x9
Tables,figures,index
Contents
Foreword xiGary Paul Nabhan
Acknowledgments xiii
Introduction xvPeter Friederici
PART I. The Context for Restoration 1
Chapter 1.The“FlagstaffModel” �Peter Friederici
Chapter 2.TheEvolutionaryandHistoricalContext ��W. Wallace Covington
Chapter 3.FirstPeoplesinthePines:HistoricalEcologyofHumansandPonderosas �8Thom Alcoze
�1Chapter 6: Ecological Restoration as Thinking Like a Forest
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Chapter 4.EcologicalandMarketEconomics �8P. J. Daugherty and Gary B. Snider
Chapter 5.TheGovernanceEnvironment:LinkingScience,Citizens,andPolitics �0Hanna J. Cortner
Chapter 6.EcologicalRestorationasThinkingLikeaForest 81Max Oelschlaeger
PART II. Restoring Ecosystem Functions and Processes 93
Chapter 7.ThePonderosaPineForestPartnership:Ecology,Economics,andCommunityInvolvementinForestRestoration 99William H. Romme, Mike Preston, Dennis L. Lynch, Phil Kemp, M. Lisa Floyd, David D. Hanna, and Sam Burns
Chapter 8.FuelsandFireBehavior 1��G. Thomas Zimmerman
Chapter 9.SoilsandNutrients 1��Paul C. Selmants, Adrien Elseroad, and Stephen C. Hart
Chapter 10.Hydrology 1�1Malchus B. Baker Jr.
Chapter 11.AssessingLandscape-LevelInfluencesofForestRestorationonAnimalPopulations 1��James Battin and Thomas D. Sisk
PART III. Restoring and Protecting Biological Diversity 191
Chapter 12.HealingtheRegionofPines:ForestRestorationinArizona’sUinkaretMountains 19�Peter Friederici
Chapter 13.TreeHealthandForestStructure �1�Joy Nystrom Mast
Chapter 14.UnderstoryVegetation ���Julie E. Korb and Judith D. Springer
Chapter 15.ExoticInvasivePlants ��1Carolyn Hull Sieg, Barbara G. Phillips, and Laura P. Moser
Chapter 16.Vertebrates ��8Carol L. Chambers and Stephen S. Germaine
Chapter 17.ArthropodResponses:AFunctionalApproach �8�Karen C. Short and José F. Negrón
Chapter 18.Threatened,Endangered,andSensitiveSpecies �0�Paul Beier and Joyce Maschinski
�� Ecological Restoration of Southwestern Ponderosa Pine Forests
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PART IV. Conducting Restoration: Practical Concerns 329
Chapter 19.Community-BasedForestRestoration ���Ann Moote
Chapter 20.EcologicalRestorationintheUrban–WildlandInterface ���John M. Marzluff and Gordon A. Bradley
Chapter 21.AirQualityandSmokeManagement ��1Gretchen Barkmann
Chapter 22.RestorationandCulturalResources �8�Helen C. Fairley
Chapter 23.Monitoring �0�Peter Z. Fulé
Chapter 24.AdaptiveManagementandEcologicalRestoration �1�Carol Murray and David Marmorek
Conclusion: KeyConceptsandQuestionsinAdaptiveEcosystemRestorationofPonderosaPineForestEcosystems ��9W. Wallace Covington and Diane Vosick
Appendix 1:SpeciesMentionedinText ���
Appendix 2: Threatened,Endangered,andSensitiveVertebrateSpeciesinArizona,NewMexico,SouthUtah,andColorado ��9
Appendix 3:ArizonaThreatened,Endangered,andSensitivePlantsPotentiallyAffectedbyPonderosaPineForestRestoration ��0
Appendix 4: ColoradoThreatened,Endangered,andSensitivePlantsPotentiallyAffectedbyPonderosaPineForestRestoration ���
Appendix 5: NevadaThreatened,Endangered,andSensitivePlantsPotentiallyAffectedbyPonderosaPineForestRestoration ���
Appendix 6:NewMexicoThreatened,Endangered,andSensitivePlantsPotentiallyAffectedbyPonderosaPineForestRestoration ��0
Appendix 7: UtahThreatened,Endangered,andSensitivePlantsPotentiallyAffectedbyPonderosaPineForestRestoration ���
References ���
AbouttheContributors ���
Index ���
��Chapter 6: Ecological Restoration as Thinking Like a Forest
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From chapter 6, “Ecological Restoration as Thinking Like a Forest,” by Max Oelschlaeger
Ecological Restoration in Ecosystem Context
FrankGolley(199�)arguesthatthe“ecosystemcon-cept” militates against the theoretical separation ofevolvedhumansystems,orculture(carriedbysym-boliccodes),fromevolvedbiologicalsystems,orna-ture (carried by genetic codes). That separation, hecontinues, is not only conceptually untenable, butdangerous to the sustainability of cultural-naturalsystems.Themuddlethatcharacterizesrestorationofsouth-westernponderosaforestsispreciselyacaseinpoint.Why? Because these ecosystems are increasinglyand predominantly artifactual, shaped more by hu-managencythannaturallyevolved,moretheconse-quence of cultural narratives than of genetic codes.Theevolvingnarrativeofecologicalrestorationrec-ognizestheiranthropogenicnature.Italsodreamsofrestoringthese forests tohealthbyuncouplingour-selves from them, by taking actions that incremen-tallynudgetheforestsontotrajectoriesofrecovery.This evolving conversation, whatever its uncertain-ties,isahigh-mindedeffort—ecocentricratherthan
narrowly anthropocentric. Ecological restorationpresupposes that biophysically evolved systems andcreatures have intrinsic value. The community ofrestorationistsisbeginningtothinkandactinwaysfirstconceptualizedbyAldoLeopold(19�9).Hear-guedthatgoverninglandmanagementpracticeswerefundamentally flawed, and that new ways of think-ingthataddresstheevolvedrealityofecosystemsandthedeleteriousoutcomesofecologicallymyopichu-man actions were essential to long-term ecosystemintegrity,stability,andbeauty.Inparticular,Leopolddistinguished views that classify natural systems asresources to be economically exploited from thosethat categorize them as something more than rawmaterials forhumanpurposes—even if theycanbeeconomicallyexploited.Inhisessay“ThinkingLikea Mountain,” Leopold shows how ranchers thinkaboutmontaneecosystemsascowfactories, loggersthink about them as wood factories, and huntersthinkaboutthemasdeerfactories.Butnonethinkslike the mountain itself, a naturally evolved systemwith a temporal dimension and evolved structurethateludethenativerangeofhumanperceptionsandestablished conceptual schemes. Leopold’s intent istomakeclearthedifficultyhumansfaceinthinkingecologically. In fact, without expanding the tempo-ralscaleofperceptionandescapingconventionsthatoverdeterminetheirthinking,humanscannotthinkecologically.For those caught in the muddle, the challenge ofrestorationmightbedescribedas coming to “thinklikeaforest.”Andmaybe,justmaybe,acceptingthatchallenge might help us begin to understand whystakeholders are conflicted. Why? Because humanshaveverylittleexperience,almostnone,inthinkinglike a forest. Since the advent of Neolithic culture,webig-brainedtwo-leggedshaveprimarily thoughtaboutthenaturalworld,whetherlandscapesorspe-cies,fromtheperspectiveofaself-interestedspecies.In the modern world, that self-interest has playedoutthroughnarrow,fundamentallyeconomicjudg-ments; forest policies and sciences have primarilyservedtheendsofexploitation.Public-lands forests would doubtless be in evenworseconditionwithout theeffortsofGiffordPin-chot,whostoppedalonghistoryoflaissez-faireex-ploitation.Buttheethicalcredobehindprogressiveresource conservation was—and remains—largely
About This Excerpt
Withyearsofdroughtparchingthesouthwest-ernregionof theUnitedStates,agrowinghu-manpopulationmovingintodrasticallyalteredponderosapineforests,andseverewildfiresoc-curringregularlyintheregion,Ecological Resto-ration of Southwestern Ponderosa Pine Forestsisa timelyandmuch-neededvolumewith infor-mationthatisalsorelevantoutsidethisregion.In this book, Peter Friederici brings togetherpractitionersand thinkers fromawidevarietyoffieldstosynthesizewhatisknownabouteco-logicalrestorationinponderosapineforests.Inthis excerpt, Max Oelschlaeger argues that allparticipantsintheseforestsmustseethemselvesaspartofthe“foreststory”forrestorationtobesuccessful.
�� Ecological Restoration of Southwestern Ponderosa Pine Forests
SER Restoration Reader
economic.Fireexclusionandsuppressiongrewoutofthesameideologythatledtothedammingofwildrivers.Justasfree-flowingriverswereconceptualizedas wastingwater, so forestfireswereviewedasde-stroyingvaluabletimber,andthegrassesthatnatu-rally carried frequent, low-intensity fires throughthepineswereseenas fodder thatcouldgrowbeefandmutton.Today’smulti-usestatutoryframework(often termed “multi-abuse” by environmentalists)is firmly rooted in utilitarianism. Forest science it-selfhasbeenmesmerizedbyclassicalphysicsanditsquestforpredictiveknowledge,andbymarketeco-nomics,whichviewsforestsasrawmaterialsonly.Forest science fails to recognize its roots in thescientificrevolutionofthe1�00sandthenotionthatthroughsciencehumanswouldbecomethemastersandpossessorsofnature.Theresulting“conspiracyofoptimism”(Hirt199�)heldthatbyapplyingsci-ence to management and policy we could excludefire, harvest timber, eradicate insects, graze thegrasses, provide recreational opportunities— andstillhavehealthy,flourishingforests.But forestsci-encewasuntil recentlyblind to theevolvedroleoflow-intensitygroundfiresinponderosapineecosys-tems,ignorantoftheunsustainabilityofcommercialforestryinthearidSouthwest,indifferenttothead-verseconsequencesofgrazing,andoblivioustotheharmfulconsequencesofsomerecreationaluses.Politically the forestshavebeenheld in the lockofthe“irontriangle”(Chapter�)madeupofcommer-cial interests, western congressional representativesand senators, and entrenched land managementbureaucrats, including forest scientists. It assured astreamoftimber,employment,andsubsidiesforthecommercial interests, campaign contributions andreelectionformembersofCongress,andfundingformanagementagencies—butnoneofthesestakehold-erswerethinkinglikeaforest.Rather,allconsideredtheforestacommodity,rawmaterialtofuelaneco-nomicengine.The situation finally changed during the 1990s, ascommercial forestry on public lands dramaticallydeclined. Yet environmental advocates continue toworry,understandably,aboutthereestablishmentofcommercialforestry.Today’sgreatestdangertopon-derosa forests is not the sawyer but crown fire, butproposalsformultigenerational,landscape-scaleeco-
logicalrestorationprojectsthatwouldincrementallylessenandultimatelyeradicate thedangerofcrownfireareviewedbysomeadvocacygroupsasaTrojanHorse.Giventhehistoryoftheseforests,thispositionisnotincomprehensible.YetasIlistentothediversecommunityofecologicalrestorationists, I hear hope that the basic composi-tion, structure, and function of ecosystems drivenfarfromtheirnaturaldynamicequilibriummightberestored.Whoamongus—otherthanprofiteerslook-ingforaquickbuckandthefirststageoutoftown—couldbeagainstsuchagoal?Wehavelearnedthattheanthropogenicecosystemstowhichwearesocloselycoupled are, whatever previous intentions, subjectto catastrophic, costly, and irreversible changes. Ihave been somewhat surprised when people whomI respect for their untiring defense of southwesternforestsclaimthatecologicalrestorationisafastroadto Hell—to forest conditions worse than those thatexist now. This proves, at least, that “high-minded-ness”comesatthecostofcognitivedissonance.Butcognitivedissonancecanbeproductivebyinvitingadeeperandricherunderstandingofthetangleofis-suesconcerningrestoration.
Sweet Reason
Humanbeingsaregenerallynotrisk-takers.Wetendtolikethingssettled,sureandcertain.Politicians,es-pecially,donotlikerisk.Landmanagersdonotlikerisk.Theyneedtobeincontroloftheforest.Scientificresearchersattempttominimizeriskofvarioustypesof methodological mistakes. Environmentalists donotlikerisks,either,especiallyleadersofmanyenvi-ronmentalorganizations,forwhomcompromisehasbecomeadreadedword.Andallofus,whenitcomestoethical judgment,hateevenawhiffofrelativism.Whatwelikeareevaluativejudgmentsthataparticu-largoalisclearlybetterthananyothergoal.Thus,wetoooftenacceptutilitarianarguments.Yet thedeepest thinkersofourtime, like theNobelPrizewinnerIlyaPrigogine,arguethattheendofcer-tainty isathand(Prigogine198�,199�).Fallibilismrules.Nojudgmentsofpolicy,science,orethicsareanythingmoreor less than fallible.Remarkablead-vancesinunderstandingthebiologicalbasisofhumannaturehavetrailedinthewakeoftheoreticaldevelop-mentssuchasGödel’sproofandHeisenberg’suncer-
��Chapter 6: Ecological Restoration as Thinking Like a Forest
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taintyprinciple.Asaresult,somesaywehavemovedbeyondbothobjectivism(thebeliefthathumanscanhavesureandcertainknowledgethatisgoodforallpeople inallplacesatall times)andrelativism(thebeliefthathumanscannevermakeknowledgeclaimsthatescapetheparticularityoftimeandplace,personandclass,orpoliticalideology,nationalistfervor,andreligiousdogma).Oneconstructivealternativetoeitherobjectivismorrelativismistheconjecturethathumanslearnastheygo.Weare,simply,falliblelearners.Learninghowtothinklikeaforestisanexerciseinfallibilitythatper-hapsbeginswith the recognition thatmostofwhatwethoughtweknewaboutforestsisnotdefensible.Clearcutting,forexample,defendedbyseveralgener-ationsoftimbermanagersasscientificallygroundedandthusasrational forestmanagement, isclearlyafailedeconomicstrategythatishardonwesternfor-ests and associated human communities (Langston199�; Power 199�). Similarly, fire exclusion withinponderosa pine forests (though not necessarily aturban–wildlandinterfaces)isunecologicalandeco-nomicallywasteful,leadingtoever-increasinglossofponderosaforeststocrownfire,destructionofwater-sheds,lossofcriticalhabitatforendangeredspecies,dramatically increasing expenditures to fight fires,lossofproperty,andeventhelossofhumanlife(US-GAO1998).Thatsaid,arewelearningtothinklikeaforest?May-be,onlymaybe.Weremaincollectivelyat thesheerbeginningofalearningcurvethatslopesupsteeplyandonlygraduallyflattensout.Thescientificprocessofconjectureandrefutation—orfalliblelearning—isfarthest along inansweringquestionone:Whatarethecausalfactorsthathaveledtopresentconditionsandthatmightbemanipulatedtohealponderosafor-ests?These factorsareaddressed inParts IIandIIIofthisvolume.However,stakeholdergroups,includ-ingresearchers,arebeginningtorealizethatscience,howevernobleinitsquestfortruth, isnotthefinalsolution(Chapter�).Neitherthesciencethatexiststoday, nor future advances, will ever be complete.Scientificinquiryitselfisincreasinglyunderstoodasexistingwithinandpartiallyframedbycomplicatedhistorical, social, political, and economic contexts(Sarewitz199�).Further,scientificinquiryinevitablyhasmultiplepublicdimensions,includingacommit-ment to open and continuing public inquiry, com-
ment, and even participation (Lee 199�; WildlandsProject�001–�00�).Enterquestiontwo;namely,policy—Whatameliora-tiveactionsareappropriate,overwhattimeframe,atwhatcost?—andthepolicyprocess—Whatprocessesare appropriate in establishing forest policy? Manycommentatorsremarkontheparadoxofthepublic-landsWest,whichatoneandthesametimemanifestsaninspiring“geographyofhope”(Stegner198�)whileyielding first and typically a politics of exploitation(Wilkinson199�)thatgiveswayfinallytoapoliticsofstalemate(Kemmis1990).Asso-callednewWesternhistorianshavemadeclear(Limerick198�),thepost-settlement West was overdetermined by ideologieslittle suited to its landscapes, and thereby subjectedto short-term exploitation. Only recently has thepolicyprocessstartedtochange,withavarietyofex-perimentsininclusive,collaborativeprocesses.Giventhe diversity of opinion among stakeholder groups,though, and the inability of various experiments incollaborativeprocess toovercomethesedifferences,itislikelythatthefederalgovernmentwillcontinuetopourtensofbillionsofdollarsintotheblackholeoffireexclusionandsuppression(Chapter�).Asfarasthepolicyprocessthatmightestablishlandscape-scaleecologicalrestorationprojectsisconcerned,fal-liblelearningremainsadream.Finally,questionthree,thatofintention:Whatreasonslegitimateaproposedpolicy,policyprocess,orscientificclaim?Clearly,giventhemuddlethatexistsandthein-creasingfrequencyofcrownfires,thestatusquoisnotalegitimatealternative.Prolongingthemuddlemightservetheagendasofsomestakeholdergroups,butsuchstalemateblocksthinkinglikeaforest.Policies for ecological restoration are informed byscienceonthequantitativesideandbyethicsonthequalitativeside.Scienceitselfisinevitablyvalue-lad-en,andthelegislativeframeworkthatestablishedandgovernsourpubliclands—includingsuchlegislationastheWildernessActandEndangeredSpeciesAct—isitselftheresultofso-calledcitizenchoices(Sagoff1988), or affirmations by the American people ofwhatcountsandwhatdoesnot.Thoughnarrowlyfo-cused,largelyself-interestedeconomicmotivescon-tinuetoplaya largerole inthemanagementofournational forests and parks, their establishment did
�� Ecological Restoration of Southwestern Ponderosa Pine Forests
SER Restoration Reader
reflectAmerica’scollectivecommitment to intrinsicvaluesofthenatural(orseminatural)world.Ecologicalrestorationnecessarilyservestheselargerpurposes(Bateson19�9;Golley199�).Thus,restora-tionisconflictedpartlybecauseitimplicitlycontainsdefinitions of our humanity—notions of whom weare,wherewearegoing,andwhyweshouldgothere,orineffectamoralmap(Jordan�00�).
Excerpted from Ecological Restoration of Southwest Ponderosa Pine Forests edited by Peter Friederici. Copyright © 2003 by Island Press. Excerpted by permission of Island Press. All rights reserved. No part of this excerpt may be reproduced or reprinted without permission in writing from the publisher. Island Press grants permission to forward this unaltered electronic document to friends, colleagues, and other interested parties.
aSSEmbly RulES and REStoRation Ecology
Assembly Rules and Restoration EcologyBridging the Gap between Theory and Practice
EditedbyVickyM.Temperton,RichardJ.Hobbs,TimNuttle,andStefanHalle
Cloth,$90.00,ISBN1-��9��-���-�
Paper,$��.00,ISBN1-��9��-���-1
�00�.���pages.�x9
Tables,figures,index
Contents
Preface xiii
Chapter 1.Introduction:WhyAssemblyRulesAreImportanttotheFieldofRestorationEcology 1Vicky M. Temperton, Richard J. Hobbs, Tim Nuttle, Marzio Fattorini, and Stefan Halle
PART I. Assembly Rules and the Search for a Conceptual Framework for Restoration Ecology 9
Chapter 2.AdvancesinRestorationEcology:InsightsfromAquaticandTerrestrialEcosystems 10Stefan Halle and Marzio Fattorini
Chapter 3.TheSearchforEcologicalAssemblyRulesandItsRelevancetoRestorationEcology ��Vicky M. Temperton and Richard J. Hobbs
�8 Assembly Rules and Restoration Ecology
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Chapter 4.AssemblyModelsandthePracticeofRestoration ��Julie L. Lockwood and Corey L. Samuels
PART II. Ecological Filters as a Form of Assembly Rule 71
Chapter 5.EcologicalFilters,Thresholds,andGradientsinResistancetoEcosystemReassembly ��Richard J. Hobbs and David A. Norton
Chapter 6.TheDynamicEnvironmentalFilterModel:HowDoFilteringEffectsChangeinAssemblingCommunitiesafterDisturbance? 9�Marzio Fattorini and Stefan Halle
Chapter 7.BeyondEcologicalFilters:FeedbackNetworksintheAssemblyandRestorationofCommunityStructure 11�Lisa R. Belyea
PART III. Assembly Rules and Community Structure 133
Chapter 8.Self-OrganizationofPlanktonCommunities:ATestofFreshwaterRestoration 1��Carmen Rojo
Chapter 9.FunctionalGroupInteractionPatternsAcrossTrophicLevelsinaRegeneratingandaSeminaturalGrassland 1��Winfried Voigt and Jörg Perner
Chapter 10.Structure,Dynamics,andRestorationofPlantCommunities:DoArbuscularMycorrhizaeMatter? 189Carsten Renker, Martin Zobel, Maarja Öpik, Michael F. Allen, Edith B. Allen, Miroslav Vosátka, Jana Rydlová, and François Buscot
Chapter 11.ModelingofPlantCommunityAssemblyinRelationtoDeterministicandStochasticProcesses ��0Gerrit W. Heil
Chapter 12.ApplicationofStableNitrogenIsotopestoInvestigateFood-WebDevelopmentinRegeneratingEcosystems ���Jan Rothe and Gerd Gleixner
PART IV. Assembly Rules in Severely Disturbed Environments 265
Chapter 13. TheRolesofSeedDispersalAbilityandSeedlingSaltToleranceinCommunityAssemblyofaSeverelyDegradedSite ���Markus Wagner
Chapter 14.OrderofArrivalandAvailabilityofSafeSites:AnExampleofTheirImportanceforPlantCommunityAssemblyinStressedEcosystems �8�Vicky M. Temperton and Kerstin Zirr
�9Chapter 5: Ecological Filters, Thresholds, and Gradients in Resistance to Ecosystem Reassembly
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Chapter 15.AreAssemblyRulesApparentintheRegenerationofaFormerUraniumMiningSite? �0�Hartmut Sänger and Gottfried Jetschke
Chapter 16.TheRoleofNutrientsandtheImportanceofFunctionintheAssemblyofEcosystems ���Anthony D. Bradshaw
PART V. Disturbance and Assembly 341
Chapter 17.Disturbance,Succession,andCommunityAssemblyinTerrestrialPlantCommunities ���Peter S. White and Anke Jentsch
Chapter 18.Disturbance,AssemblyRules,andBenthicCommunitiesinRunningWaters:AReviewandSomeImplicationsforRestorationProjects ���Christoph D. Matthaei, Colin R. Townsend, Chris J. Arbuckle, Kathi A. Peacock, Cornelia Guggelberger, Claudia E. Küster, and Harald Huber
Chapter 19. HowStructureControlsAssemblyintheHyporheicZoneofRiversandStreams:ColmationasaDisturbance �89Eva-Barbara Meidl and Wilfried Schönborn
Synthesis �09
Chapter 20.AssemblyRulesandEcosystemRestoration:WheretofromHere? �10Tim Nuttle, Richard J. Hobbs, Vicky M. Temperton, and Stefan Halle
AbouttheContributors ���
Index ��9
80 Assembly Rules and Restoration Ecology
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From chapter 5, “Ecological Filters, Thresholds, and Gradients in Resistance to Ecosystem Reassembly,” by Richard J. Hobbs and David A. Norton
Thewayinwhichbiologicalcommunitiesareassem-bledfromtheregionalpoolofbiodiversityhasreceivedincreasingstudy,andthequestionofwhetherrecog-nizable“assemblyrules”existhasbeenexamined(seeChapter�).Thereisnowevidencetosuggestthatas-semblyrulesmaybefoundforbothexperimentalandnaturalcommunities.However,thereisalsoevidencetosuggestthatdifferentassemblagesresultfromdif-ferentstartingconditions,orderofspeciesarrivalorintroduction,andtypeandtimingofdisturbanceormanagement.Otherchaptersinthisbookdiscusstheongoingde-bateoverhowthebioticelementsofecosystemsas-semble, particularly following disturbance, and ex-amine whether this process is relevant to ecologicalrestoration. In Hobbs and Norton (199�), we pro-posedsomegeneralprinciplesthatmighthelpbuildabroadframeworkforrestorationecology.Inthischap-ter,weexplorevariousaspectsofecosystemdynamicsandrestorationtodevelopsuchaframeworkfurther.Specifically,welookathowageneralframeworkcanserveasabasisforbetterunderstandingwhatcanbeachieved in restoration at a particular site. We startbyreviewingrecentdevelopmentsinecologicalcon-ceptsandexamininghowtheyradicallyaltertheway
inwhichweshouldconsiderecosystemdynamicsandrestoration.Inparticular,wereflectontheimportanceofalternativestablestatesinecosystemsandthedriv-ers that force transitions between states. We look atthesestateandtransitionapproachesinarestorationcontext,particularlyinrelationtorestorationthresh-olds.Wethenconsidertheconceptofbioticandabi-otic filters and examine whether it meshes with theideasofstates,transitions,andthresholdstoassistindeveloping a comprehensive framework for ecosys-temrestoration.
New Ecosystem Paradigms
Ecologicalconceptshavechangeddramaticallyoverthe past �0 years (Pickett and Ostfeld 199�, Pickettet al. 199�). It is now increasingly recognized thatecosystems are complex, dynamic entities that varyatmultiplescalesinbothspaceandtime.Thecom-plexdynamicbehaviorofecosystemsoftenmakesitdifficulttounderstandhowtheyfunctionandtopre-dicttheoutcomesofanygiveneventormanagementactivity(Hobbs1998,HobbsandMorton1999,Pahl-Wostl 199�). Following Hobbs and Morton (1999),wenowoutlinesomeofthemainchangesinecologi-calthinkingthatarerelevanttounderstandingeco-logicalassemblyandrestoration.
The Flux of Nature
Ecologists historically viewed the natural world asa fundamentally stable place in which each specieshaditsorderedpositionwithinacommunityandinwhich any disturbance would result in an orderedsuccessional progression leading back to the origi-nalclimaxstate(Christensen1988).Ecologicalcom-munitieswereconsideredtobeorganized,patternedcollections of coevolved species that incompatiblespeciescouldnoteasilypenetrate(Simberloff198�).Ecologistsnowspeakofthisviewastheequilibriumparadigm.Inrecentyears,wehaveseenthisnotionoforganizationandstabilitygivewaytotheviewthatthenaturalworldisdynamic.Inthisparadigm,eco-systemsarecharacterizedmorebyinstabilitythanbypermanence.Ecosystemsarealsomarkedbyfrequentdisturbances thatcontinuallypush them inalterna-tivedirections insteadof causing them to return totheir original condition. We now see ecosystems as
About This Excerpt
How are ecosystems assembled? How do thespecies that make up a particular biologicalcommunityarriveinanarea,survive,andinter-actwithotherspecies?Howcanwereturnade-gradedareatoafunctioningecosystemthatcanserveasahabitatorperformusefulecosystemservices? Assembly Rules and Restoration Ecol-ogysetsrestorationecologyinafirmtheoreticalframework that is both readable and rigorous.Inthisexcerptfromchapter�,RichardJ.HobbsandDavidA.Nortonconsidertheinteractionofaspectsofecologicalfiltersindetermininghowwellrestorationprojectssucceed.
81Chapter 5: Ecological Filters, Thresholds, and Gradients in Resistance to Ecosystem Reassembly
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characterizedbymoreorlessunpredictableindivid-ualisticspeciesresponsesratherthanbypredictableandcorrelatedspeciesresponses.The nonequilibrium paradigm just described recog-nizesthatthenaturalworldisanuncertainplaceinwhichdisturbancesareconstantlycausingalterationsinthecompositionofassemblagesandinthespatialpatternsoftheenvironment(Fiedleretal.199�,Pick-ettetal.199�,PickettandWhite198�,Sousa198�).Thisviewdoesnotsuggestthatecologicalequilibriadonotexistbutratherthattheyarescale-dependentand embedded in nonequilibrial conditions. Nev-ertheless, the nonequilibrium paradigm does implythatpredictableendpointstothesuccessionalprocessfollowing disturbance are rare, that multiple stablestatesmayexist,andthatsomequasi-stablestatescanpersistforlongperiods.
Multiple Stable States
Disturbanceinevitablysetsinmotionsomeformofsuccession.Currentdiscussionofecosystemdevelop-mentfollowingdisturbanceaskswhetherconceptsofindividualistic assembly and multiple endpoints aremore appropriate than classical successional theory(Youngetal.�001).Thecourseofsuccessioncanbedifficult to predict, because the direction the eco-system or assemblage takes is contingent upon theparticularcircumstancesof thedisturbanceandthenatureofthebiophysicalconditionsthatprecedeandfollowit.Thenotionofcontingencyimpliesthathis-torymattersinpatternsandprocessesofcommunitychange.Asaconsequence,theendpointofasucces-sionalprocessisnotapredictablyuniformoutcome;instead,severalstatesarepossible,dependingonthecontingent circumstances (Hobbs 199�, Noble andSlatyer1980).Ageneralfeatureofmanyecosystemsisthepotentialforthesystemtoexistinanumberofdifferentstates,dependingonbothpastandpresentbioticandabioticfactors.
Patchiness and Landscape Ecology
Recognitionoftheimportanceofspatialandtempo-ralvariability,togetherwiththeincreasedavailabilityofsuitabletoolsforanalyzingit,isattherootoftheemergingdisciplineoflandscapeecology.Theunder-standing and management of the natural world de-
pendsasmuchontheanalysisofflowsofresourcesacrossecosystemsasitdoesonthedetailedstudyofindividualplaces.Oneoftheprincipalissuesunder-pinninglandscapeecologyisrecognitionofthevitalimportanceofpatchiness(Levin1989,Ostfeldetal.199�,TurnerandGardner1991).Patchinessfocusesonthespatialmatrixofecologicalprocessesandem-phasizesthefluxesofmaterialsandorganismswithinandbetweendifferentpartsofthelandscape.
Thresholds in Restoration
Therecentchangesinthewayecologicalsystemsareviewedhaveanumberoflessonsforrestorationecol-ogy.Ifecosystemsarenonequilibrium,patchy,andli-abletoexistinanumberofdifferentstates,thenres-torationgoalsneedtotakethesefacts intoaccount.Aimingforasingleendpointmaynotbevalidormayconstrain the restoration endeavor too much. Fur-thermore, it seems likely that formanyecosystems,restorationthresholdsexistasaresultofhumanac-tivities that prevent the system from returning to alessdegradedstatewithouttheinputofmanagement,restoration,andaftercareeffort(Aronsonetal.199�a;HobbsandHarris�001,Whisenant1999).Whisenant (1999) has recently suggested that twomaintypesofsuchthresholdsexist,onecausedbybi-oticinteractionsandalterationsandtheotherbyabi-oticalterations,transformations,or inherent limita-tions(Figure�.1).Ifthesysteminquestionhasbeendegradedmainlyasaresultofbioticchanges(suchasgrazing-inducedchangesinvegetationcomposition),restorationeffortsshouldfocusonbioticmanipula-tionsthatremovethedegradingfactor(forexample,thegrazinganimal)andadjustthebioticcomposition(forexample,replantinglostspecies).If,ontheotherhand,thesystemhasbecomedegradedasaresultofchanges in abiotic features (such as soil erosion orchanged hydrology), restoration efforts must focusfirstonremovingthedegradingfactorandrepairingthe physical and/or chemical environment (for ex-ample,toreinstateaparticularhydrologicalregime).Thereislittlepointinfocusingexclusivelyonbioticmanipulationand ignoringtheabioticproblems. Inotherwords,systemfunctioningshouldbecorrectedormaintainedbeforequestionsofbioticcompositionandstructureareconsidered.Takingsystemfunctionintoaccountprovidesausefulframeworkforinitial
8� Assembly Rules and Restoration Ecology
SER Restoration Reader
assessmentofthestateofthesystemandsubsequentselection of repair measures (Ludwig et al. 199�,TongwayandLudwig199�).Where function isnotimpaired,restorationcanthenfocusoncompositionandstructure.Notethat thethresholdmodel(seeFigure�.1)sug-gests that the biota simply respond passively to theabioticenvironment;thatis,bioticthresholdsalwayscomeafterabioticones.Insomesituations,however,thepresenceofakeystonespeciesor“ecosystemengi-neers”mayberequiredtochangetheabioticenviron-ment.Hence,bioticmanipulationmayberequiredinsomecasestoovercomeanabioticthreshold.
Excerpted from Assembly Rules and Restoration Ecology edited by Vicky M. Temperton, Richard J. Hobbs, Tim Nuttle, and Stefan Halle. Copyright © 2004 by Island Press. Excerpted by permission of Island Press. All rights reserved. No part of this excerpt may be reproduced or reprinted without permission in writing from the publisher. Island Press grants permission to forward this unaltered electronic document to friends, colleagues, and other interested parties.
Figure 5.1: Conceptual model of transitions between undegraded and degraded ecosystem states and the presence of biotic and abiotic thresholds (after Whisenant 1999).
thE hiStoRical Ecology handbook
The Historical Ecology HandbookA Restorationist’s Guide to Reference Ecosystems
EditedbyDaveEganandEvelynA.Howell
ForewordbyCurtMeine
Cloth,$�0.00,ISBN9�8-1-��9-�����-9
Paper,$��.00,ISBN1-�9���-0��-9
�00�.�88pages.�x9
Tables,figures,boxes,index
Contents
Figures, Tables, and Boxes ix
Acknowledgments xiii
Foreword xvCurt Meine
Preface to the 2005 Edition xxiDave Egan
Introduction 1Dave Egan and Evelyn A. Howell
Part I. Cultural Evidence 25
Chapter1.Archaeology,Paleoecosystems,andEcologicalRestoration �9Michael J. O’Brien
8� The Historical Ecology Handbook
SER Restoration Reader
Chapter 2.TheContributionofEthnobiologytotheReconstructionandRestorationofHistoricEcosystems ��M. Kat Anderson
Chapter 3.ThePleasuresandPitfallsofWrittenRecords ��Michael Edmonds
Chapter 4.OralHistory:AGuidetoItsCreationandUse 101James E. Fogerty
Chapter 5.MapsandPhotographs 1�1Tina Reithmaier
Chapter 6.GovernmentLandSurveyandOtherEarlyLandSurveys 1��Gordon G. Whitney and Joseph DeCant
Part II. Biological Evidence 173
Chapter 7.InferringForestStandHistoryfromObservationalFieldEvidence 1��P. L. Marks and Sana Gardescu
Chapter8.UsingDendrochronologytoReconstructtheHistoryofForestandWoodlandEcosystems 199Kurt F. Kipfmueller and Thomas W. Swetnam
Chapter 9.Palynology:AnImportantToolforDiscoveringHistoricEcosystems ��9Owen K. Davis
Chapter 10.PackratMiddensasaToolforReconstructingHistoricEcosystems ���David Rhode
Chapter 11.TechniquesforDiscoveringHistoricAnimalAssemblages �9�Michael L. Morrison
Chapter 12.Geomorphology,Hydrology,andSoils �1�Stanley W. Trimble
Chapter 13.InferringVegetationHistoryfromPhytoliths ���Glen G. Fredlund
Part III. Synthesis: Case Studies Using Reference Conditions 363
Chapter 14.UsingHistoricalDatainEcologicalRestoration:ACaseStudyfromNantucket ���Peter W. Dunwiddie
Chapter 15.AMultiple-ScaleHistoryofPastandOngoingVegetationChangewithinIndianaDunes �91Kenneth L. Cole
8�Chapter 8: Using Dendrochronolgy to Reconstruct the History of Forest and Woodland Ecosystems
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Chapter 16.ImplementingtheArchaeo-environmentalReconstructionTechnique:RediscoveringtheHistoricGroundLayerofThreePlantCommunitiesintheGreaterGrandCanyonRegion ���Thom Alcoze and Matt Hurteau
Chapter 17.DocumentingLocalLandscapeChange:TheSanFranciscoBayAreaHistoricalEcologyProject ���Robin Grossinger
AbouttheContributors ���
Index ���
8� The Historical Ecology Handbook
SER Restoration Reader
About This Excerpt
Afundamentalaspectoftheworkofecologicalrestorationistorediscoverthepastandbringitintothepresent.DaveEganandEvelynHowellhave assembled twenty-three experts who de-scribetechniquesfocusingonculturallyderivedevidence(documents,maps,photographs,landsurveys, oral history) and biological records(woodlot surveys, tree rings, pollen, packratmiddens, opal phytoliths, animal remains, re-cords of changes in soil and hydrology). Thisexcerptdiscussestreeringsasasourceofproxyinformationthatcanbeusedinreconstructingandunderstandingthehistoryofpastcultures,landscapes,andenvironments.
From chapter 8, “Using Dendrochronology to Reconstruct the History of Forest and Woodland Ecosystems,” by Kurt F. Kipfmueller and Thomas W. Swetnam
Treeringsareanimportantsourceoflong-termproxyinformation thatcanbeused inreconstructingandunderstandingthehistoryofpastcultures,landscapes,andenvironments.Dendrochronology—ortree-ringdating—reliesonthepracticeofcross-dating,whichistheassignmentofexactcalendardatestoeachan-nualringthroughthematchingofpatternsofgrowthandother tree-ringcharacteristics.Thebest-knownapplications of dendrochronology (e.g., Stokes andSmiley 19�8; Fritts 19��; Baillie 199�; Schweingru-ber199�).Thetree-ringdatingofancientcliffdwell-ingsandpueblosofthesouthwesternUnitedStates,forexample,iswidelyknownandcelebratedinbothscientificandpopularliterature(Douglass19�9;Bail-lie199�).Likewise,theuniqueinsightsderivedfromtree-ring reconstructions of past climatic variationsarecommonlyreferencedinassessmentsofclimaticchangeanditsimplicationsatglobalscales(Oldfield1998;USGCRP1999).Asomewhatlesswell-knownapplicationofdendro-chronologyisinthefieldofhistoricalecology(orpa-leoecology).Althoughthepotentialoftreeringsforecologicalresearchwasrecognizedbythefounderof
modern dendrochronology, A. E. Douglass (19�0),it is only recently that the subdiscipline of dendro-ecologyhasreceivedmuchattentionbydendrochro-nologistsorecologists(e.g.,FrittsandSwetnam1989;Schweingruber199�).In198�,forexample,aninter-nationalconferenceontheecologicalaspectsoftree-ring research resulted in seventy-nine conferencepapers (Jacoby and Hornbeck 198�), and a recenttree-ringconferencewiththebroadthemeof“Envi-ronmentandHumanity”(Dean,Meko,andSwetnam199�)containedaboutthirtypapers(outofatotalofeighty-two) that directly addressed ecological top-ics.Moreover, theutilityof tree rings inaddressingimportant ecological questions is gaining recogni-tionamongthelargercommunityofecologists.ThistrendisexemplifiedbyrecentW.S.CooperAwards(for “outstanding contributions in geobotany, phys-iographicecology,orplantsuccession”)presentedbytheEcologicalSocietyofAmerica to theauthorsoffourpapersthatmadeextensiveuseofdendrochro-nologicaltechniques(Hupp199�;Fastie199�;Arse-naultandPayette199�;LloydandGraumlich199�).Aprimaryreasonforthisexpandedinterestinden-drochronology is that both ecologists and naturalresource managers have become increasingly awareofthefundamentalimportanceofhistoricalperspec-tives. This appreciation stems, in part, from recog-nition of the ubiquity of nonequilibrium dynamicsarising from historical processes, such as climaticchange and aperiodic disturbances (Sprugel 1991).Tounderstandhowecosystemsarrivedattheircur-rentconfigurations,wemustknowaboutpasteventsandtrajectoriesofchange(Brown199�;Christensenetal.199�).Thisinterestinhistoryisreflectedinanincreasing demand for reconstructions of past eco-systemprocessesandstructuresthatwouldbeusefulin defining the “historical or natural range of vari-ability” (Morgan et al. 199�; Kaufmann et al. 199�;Landres, Morgan, and Swanson 1999; Stephenson1999;Swetnam,Allen,andBetancourt1999).Dendrochronology is particularly suited to his-torical-ecological research because trees tend to belong-lived and the variations in characteristics oftheir annual rings can be used to reconstruct longand detailed histories of the surrounding environ-ment.Anotherreasonisthatcross-dating—themostimportantprincipleandpracticeofdendrochronol-ogy—facilitates a multidisciplinary and multiple-
8�Chapter 8: Using Dendrochronolgy to Reconstruct the History of Forest and Woodland Ecosystems
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lines-of-evidence approach that is very effective inhistorical reconstruction (Swetnam, Allen, and Be-tancourt1999).Cross-datingisthematchingoftree-ringcharacteristicswithinandamongtreesacrossarangeoftemporalandspatialscalesforthepurposeofexactlydatingindividualringsandthestructuresandelementscontainedwithintherings.Cross-dat-ingismostcommonlyduetoregionalclimaticvaria-tion(e.g.,droughtandwetyears)thatcausesynchro-nous changes in tree growth processes (Douglass19�1; Stokes and Smiley 19�8; Fritts 19��). Hence,bycarryingouttree-ringcross-dating,mostdendro-chronologists are at least indirectly involved in thestudyofclimaticvariability,eventhoughtheirprima-ryfocusmaybeonthestudyofecologicaleventsandprocesses (e.g.,birthsanddeathsof trees,wildfires,insectoutbreaks,andconstructionofancientdwell-ingsandhumandemography).Theuseofdendrochronologicalprinciplesandtech-niques affords several important advantages overother dating techniques. The primary advantage ofdendrochronologyisaccuracyofdating.Theuseofdendrochronological principles ensures that the as-signmentofannualdates toa seriesof tree rings isexact.Thisaccuracyinturnfacilitatestheestablish-ment of connections between the temporal occur-rence of events and the timing of other changes tothe physical system. Without this level of accuracy,dendrochronologists cannot establish important re-lationships between tree growth and events in thesurroundingenvironment.Second, tree-ring data represent an extraordinarynaturalarchiveofecologicalvariationoverlongpe-riods of time. Depending upon the physical envi-ronmentandrateofdecay,treeringscanbeusedtoreconstructpasteventsorchangesinecologicalsys-temsspanningcenturiesand,insomecases,millen-nia. This is especially true when a large number ofsamples are cross-dated, as opposed to simple ringcounting of a few samples. Simple ring counting islimitedtemporallybythelongevityofthetreespecies
beingsampled.Thoughthismaybeverylonginsomespeciesthatattaingreatage,suchasbristleconepine(Pinus longaeva),thecross-datingofremnantmateri-al(i.e.,samplefromlogs,stumps,andstandingdeadtrees)canextendtherecordofchangeconsiderably.Thebristleconepinechronologydevelopedbycross-datingcurrentlyexceedsninethousandyears,almosttwiceaslongastheoldestcurrentlylivingindividual(theoldestlivingbristleconepinethatweknowofisaboutforty-eighthundredyearsold).Remnantmate-rialhasalsobeenanintegralpartofdevelopmentoffirehistoriesinthesouthwest(e.g.,BaisanandSwet-nam1990)andofdocumentationofchangesinforestcommunities(LaMarche19��;LloydandGraumlich199�;DonneganandRebertus1999).Another benefit of dendrochronology is that it canassist in identifying potential mechanisms of vari-ability. For instance, tree-ring-based fire history re-constructions indicate that fires occurred in manymountain ranges of the southwestern United Statesduring 1��8 (Swetnam and Baisan 199�; SwetnamandBetancourt1998) (figure8.1).Studyofhistori-caldocumentsandclimatereconstructionsfromtreeringsandcoralsindicatethattheElNino–SouthernOscillation was probably a climatic mechanism forthose events (Swetnam and Betancourt 1990). Anunusually strong El Nino event occurred in 1���.The regional climate signal is clearly evident in thegrowthcharacteristicsofprecipitationsensitiveconi-ferscollectedthroughouttheregion,withawideringformingin1���followedbyanarrowringduringthedryyearof1��8(figure8.1).Similarrelationshipsbe-tween climate and natural disturbances exist in thecaseof insect-causedepidemics,aswewilldescribelater.
Excerpted from Historical Ecology Handbook by Dave Egan and Evelyn A, Howell. Copyright © 2005 by Island Press. Excerpted by permission of Island Press. All rights reserved. No part of this excerpt may be repro-duced or reprinted without permission in writing from the publisher. Island Press grants permission to forward this unaltered electronic document to friends, colleagues, and other interested parties.
Ex Situ plant conSERvation
Ex Situ Plant ConservationSupporting Species Survival in the Wild
EditedbyEdwardO.GuerrantJr.,KayriHavens,andMikeMaunder
ForewordbyPeterH.Raven
Cloth,$90.00,ISBN1-��9��-8��-�
Paper,$��.00,ISBN1-��9��-8��-�
�00�.���pages.�x9
Tables,figures,index
Contents
Foreword xiiiPeter H. Raven
Preface xvii
Acknowledgments xxi
Introduction xxiiiGhillean T. Prance
PART I. The Scope and Potential of Ex Situ Plant Conservation 1
Chapter 1.ExSituMethods:AVitalbutUnderusedSetofConservationResources �Mike Maunder, Kayri Havens, Edward O. Guerrant Jr., and Donald A. Falk
Chapter 2.InSituandExSituConservation:PhilosophicalandEthicalConcerns �1Holmes Rolston III
89Chapter 12: Population Responses to Novel Environments: Implications for Ex Situ Plant Conservation
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Chapter 3.WesternAustralia’sExSituProgramforThreatenedSpecies:AModelIntegratedStrategyforConservation �0Anne Cochrane
Chapter 4.TheRoleofFederalGuidanceandStateandFederalPartnershipsinExSituPlantConservationintheUnitedStates ��Kathryn L. Kennedy
Chapter 5.ExSituSupporttotheConservationofWildPopulationsandHabitats:LessonsfromZoosandOpportunitiesforBotanicGardens 8�Mark R. Stanley Price, Mike Maunder, and Pritpal S. Soorae
PART II. Tools of the Trade 111
Chapter 6.PrinciplesforPreservingGermplasminGeneBanks 11�Christina Walters
Chapter 7.ClassificationofSeedStorageTypesforExSituConservationinRelationtoTemperatureandMoisture 1�9Hugh W. Pritchard
Chapter 8.DeterminingDormancy-BreakingandGerminationRequirementsfromtheFewestSeeds 1��Carol C. Baskin and Jerry M. Baskin
Chapter 9.PollenStorageasaConservationTool 180Leigh E. Towill
Chapter 10.TissueCultureasaConservationMethod:AnEmpiricalViewfromHawaii 189Nellie Sugii and Charles Lamoureux
Chapter 11.ExSituConservationMethodsforBryophytesandPteridophytes �0�Valerie C. Pence
PART III. The Ecological and Evolutionary Context of Ex Situ Plant Conservation 229
Chapter 12.PopulationResponsestoNovelEnvironments:ImplicationsforExSituPlantConservation ��1Brian C. Husband and Lesley G. Campbell
Chapter 13.PopulationGeneticIssuesinExSituPlantConservation ���Barbara Schaal and Wesley J. Leverich
Chapter 14.IntegratingQuantitativeGeneticsintoExSituConservationandRestorationPractices �8�Pati Vitt and Kayri Havens
Chapter 15.EffectsofSeedCollectionontheExtinctionRiskofPerennialPlants �0�Eric S. Menges, Edward O. Guerrant Jr., and Samara Hamzé
90 Ex Situ Plant Conservation
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Chapter 16.HybridizationinExSituPlantCollections:ConservationConcerns,Liabilities,andOpportunities ���Mike Maunder, Colin Hughes, Julie A. Hawkins, and Alastair Culham
Chapter 17.AccountingforSampleDeclineduringExSituStorageandReintroduction ���Edward O. Guerrant Jr. and Peggy L. Fiedler
PART IV. Using Ex Situ Methods Most Effectively 387
Chapter 18. RealizingtheFullPotentialofExSituContributionstoGlobalPlantConservation �89Mike Maunder, Edward O. Guerrant Jr., Kayri Havens, and Kingsley W. Dixon
Appendix 1.RevisedGeneticSamplingGuidelinesforConservationCollectionsofRareandEndangeredPlants �19Edward O. Guerrant Jr., Peggy L. Fiedler, Kayri Havens, and Mike Maunder
Appendix 2. GuidelinesforSeedStorage ���Christina Walters
Appendix 3.GuidelinesforExSituConservationCollectionManagement:MinimizingRisks ���Kayri Havens, Edward O. Guerrant Jr., Mike Maunder, and Pati Vitt
Appendix 4.ExSituPlantConservationOrganizationsandNetworks ���Kevin M. James
AbouttheContributors �8�
Index �91
91Chapter 12: Population Responses to Novel Environments: Implications for Ex Situ Plant Conservation
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From chapter 12, “Population Responses to Novel Environments: Implications for Ex Situ Plant Conservation,” by Brian C. Husband and Lesley G. Campbell
Theprimarygoalofexsituplantconservationistoestablishandmaintainseedorgrowingcollectionsofwildspeciesoutsidetheirnaturalhabitat forthedi-rectorindirectpurposesofspeciesrecoveryinsitu.Suchprogramstypicallyinvolvethreestages:collec-tion from natural populations, establishment andmaintenanceofseedorgrowingmaterialoffsiteand,whenappropriate,useofexsituplantmaterialforinsitureintroductionefforts.Viewedinthisway,frominitial collection to final end use, the success of anexsituconservationprogramdependson itsabilitytoadequatelyrepresentthespeciesofinterestintheexsitupopulationand topreserve theutilityof thepopulationforfuturerecoveryefforts.Thechallengeforconservationists,then,istodeterminethegeneticanddemographicfactorsthataffecttheimplementa-tionandlong-termutilityofanexsituconservationprogram.In this chapter, we identify the critical genetic anddemographicfactorsinfluencingexsituconservationby examining relevant evolutionary principles. Webeginbyconsideringthehistoricalroleofevolution-arybiologyinplantconservationandtheneedforitsgreateruseinexsituconservation.Wearguethatthe
challengesfacingexsituconservationprogramscanbeviewedwithintheconceptualframeworkofpopu-lationsinabruptlychangingenvironments.Followingonthistheme,wecharacterizetheselectiveenviron-mentthatatransplantedpopulationwillexperienceandthedemographicconsequencesthatsuchanen-vironmentalshiftmayimpose.Wethenexplorethegeneticanddemographicfactorsthatmayinfluencethe success of such a transplantation or coloniza-tionevent.Finally,wediscusstheimplicationsofourfindingsforexsituconservationprogramsandsug-geststepsthatincreasethechancesforsuccess.
Evolutionary Biology in Ex Situ Conservation
Evolutionary biology has contributed much to thedevelopmentofconservation,particularlyasitrelatesto the protection of extant populations in situ. Forexample, the theoreticalandempirical literaturere-gardingtheecologyandgeneticsofsmallpopulations(Franklin1980;Lande1988,199�;BarrettandKohn1991;Rieseberg1991;Schemskeetal.199�;Lynchetal.199�;NewmanandPilson199�;FischerandMat-thies1998a,1998b;BataillonandKirkpatrick�000)hashelpedtoquantifytherisksofextinctionfacingmanythreatenedspecies. Inaddition,knowledgeofthe organization of genetic variation (Frankel andBrown198�;BrownandBriggs1991)hasledtotherefinementofcollectionandmanagementstrategiesusedinnationalprogramsofplantconservation(Falk1991;CenterforPlantConservation1991).Unfortu-nately,theevolutionarybiologyofexsituconserva-tionforwildspecieshasbeenlesswellexploredandtherefore has played a smaller role in conservationpractice. As a result, many ex situ collections haveinvolved a small number of threatened taxa whoserepresentation in collections is narrow (Brown andBriggs1991;Maunderetal.1999).Thegeneticbaseonwhichmanyreintroductionprogramsarefoundedislikelytobeequallynarrow.Todeterminethepotentialroleofevolutionarybiolo-gyforguidingoffsitecollectionsandrestorativeplant-ings,weconductedasurveyofrecentexsituplantingsandinsitureintroductionsforseveralNorthAmeri-canspeciesatrisk,availablethroughonlinesearches(Table 1�.1). In total, �0 cases were identified; al-though the list is far fromexhaustive, it shows that�9percentofallplantingswerebasedonpropagules
About This Excerpt
Thisbookoutlinestherole,value,andlimitsofexsituconservationandupdatesthebestman-agementpracticesforthefield.Plantconserva-tionpractitionersatbotanicgardens,zoos,andotherconservationorganizations,aswellasstu-dentsandfacultyinconservationbiology,man-agers of protected areas, and the internationalcommunity concerned with species conserva-tionwillfindEx Situ Plant Conservationavitaltool.Thefollowingexcerptfromchapter1�dis-cussestheprofoundmodificationstowhichexsitupopulationscanbesubjectedasaresultofthehorticulturalorstorageenvironment.
9� Ex Situ Plant Conservation
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fromonlyasinglesourcepopulation,and�0percentoftheseplantingswerebasedonfewerthan10sourceindividuals(Table1�.1).Clearly,collectionsofthreat-enedspecies,foreitherexsituorinsituconservation,arenecessarilyconstrainedbythelimitedavailabilityofsourcematerial(BrownandBriggs1991).Indeed,manyofthespecieslistedinTable1�.1arenotknownfrommore thana singlepopulation. It is especiallyimportantforthisreasonthatconservationprogramsconsider thegenetic (e.g., geneticvariance,popula-tiondifferentiation,inbreeding)andecological(e.g.,numberof individuals,habitatcharacteristics)attri-butesoforganismstoensurethatplantings,bothonandoffsite,areviableinthelongtermandcanmeetspecified recovery targets. Interestingly however,inour limitedsurvey,8�percentand��percentofthesecasesdidnotstateexplicitgeneticorecologicalcriteria,respectively,toguidetheirprograms.Whenthesecriteriawereconsidered,theyweremostoftenappliedtodecisionsregardingsamplingorcollectingtheoriginalmaterialbut rarely indecisions regard-ingstorageorestablishmentofplantingsoffsiteandsubsequentreintroductionefforts.Developingscientificallyinformedprogramsofexsituconservationwillinvolvemorethansimplyapplyingthetheorythatisapplicabletoinsituconservationbe-causetheirgoalsandprocedurescanbequitedistinct.In contrast to in situ methods, ex situ conservationinvolvessamplingmaterialfromexistingpopulations.Samplingerrorandlossofgeneticdiversitythroughgeneticdriftarelikelytobeimportantinbothaspectsofconservationandinfactmaybeexaggeratedinexsitueffortsbythejointeffectsofsmallsourcepopula-tionsandfinite samples.Currently, thereareseveralexcellentdiscussionsintheliteratureconcernedwiththebiologyandtheconservationrisksassociatedwithsmallpopulations(SouléandSimberloff198�;BarrettandKohn1991;Lande199�).Perhapswhatismostdistinctaboutexsituconserva-tion,incomparisonwithinsitu,isthattargetplantsare being removed from their native location andintroduced and maintained in a new environmentwhoseabioticandbioticconditionscertainlyaredif-ferentfromthatoftheoriginalpopulation.Althoughthespecificenvironmentoftheexsitucollectionwillvarywidelyamongcases,theexpectationofanabruptshiftintheexsituenvironmentwillapplyequallytoseedcollectionsandactivelygrowingplantmaterial.
Whereas inonecase (in situ) theconservationist isattemptingtofacilitatesurvivalandgrowthofanex-tantpopulation,intheotherheorsheispotentiallyaddinganewsourceofendangerment,namelymal-adaptation.Becausethebiologicalfeaturesofinsituand ex situ populations are inherently different, sotooarethebestmanagementpracticesnecessaryforsuccess. In particular, the conservation biologist isfacedwith thechallengeofcollectinga sample thatisgeneticallyrepresentativeandmaintainingitinanenvironment that may be anything but ecologicallyrepresentative of the native habitat. Furthermore,exsitucollectionsarenotanend in themselvesbutratherameanstowardthegoaloflong-termviabilityforpopulationsinsitu.Therefore,exsitucollectionsoftenmustbemanaged to simultaneouslymaintaintheirshort-termviabilityoffsiteandtheirlong-termutilityinrestorationorreintroductionefforts(Guer-rant199�).Aconceptual frameworkandsomepracticalguide-lineshavebeendevelopedforexsituconservationofcropplants(BrownandMarshall199�;SchoenandBrown199�).Thisapplicationofevolutionarybiol-ogymaynotbecompletelytransferabletowildspe-ciesbecausethegoalsandthetargetspecies for thelatteraresomewhatdifferent.Forcropspecies,exsitucollectionsaremorepermanentandserveprimarilyas sources of single characters or individual genesthatplantbreederswilltransferintolocallyadaptedstocks.Forwildorganisms,exsituprogramsoperateonashorttolong-termtimescaleandoftenoriginatefrom a smaller number of plants. In addition, theprimarygoalof theexsitucollection is to facilitatedemographicviabilityofthespeciesinthewild,notgenetic preservation, so the ex situ collection mustprovideasourceofpropagulesthatcanbeassembledintowhole,functioningpopulations.Moreover,con-servingwildspeciesoffsiteismorecomplexbecauseof their diverse and complex life histories, variablematingsystems,andlowerstoragetolerance(BrownandBriggs1991).
Excerpted from Ex Situ Plant Conservation edited by Edward O. Guer-rant Jr., Kayri Havens, and Mike Maunder. Copyright © 2004 by Island Press. Excerpted by permission of Island Press. All rights reserved. No part of this excerpt may be reproduced or reprinted without permis-sion in writing from the publisher. Island Press grants permission to forward this unaltered electronic document to friends, colleagues, and other interested parties.
wildlifE REStoRation
Wildlife RestorationTechniques for Habitat Analysis and Animal Monitoring
MichaelL.Morrison
ForewordbyPaulR.Krausman
Cloth,$�0.00,ISBN1-��9��-9��-9
Paper,$��.00,ISBN1-��9��-9��-�
�00�.�1�pages.�x9
Tables
Contents
Foreword xiSeries Introduction xvAcknowledgments xixIntroduction 1
Chapter 1. Populations 7PopulationConceptsandHabitatRestoration 8ThreeRoadstoRecovery:Breeding,Reintroduction,andTranslocation 18Lessons ��
Chapter 2. Habitat 41Definitions ��WhentoMeasure �9WhattoMeasure �9HowtoMeasure �9Lessons ��
9� Wildlife Restoration
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Chapter 3. Historic Assessments 71Background �1Techniques ��CaseStudies �9Lessons 81
Chapter 4. A Primer on Study Design 85ScientificMethods 8�MonitoringasResearch 8�PrinciplesofStudyDesign 88ExperimentalDesign 9�Lessons 100
Chapter 5. Fundamentals of Monitoring 103Definitions 10�Inventory 10�Monitoring 10�SamplingConsiderations 108AdaptiveManagement 11�ThresholdsandTriggerPoints 11�Lessons 11�
Chapter 6. Sampling Methods 119Principles 1�0AmphibiansandReptiles 1��Birds 1�0Mammals 1�8Lessons 1�9
Chapter 7. Designing a Reserve 155SelectingaSite 1��Corridors 1��Buffers 1�1Isolation 1��Fragmentation 1��
9�Chapter 1: Populations
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AreIsolationandFragmentationAlwaysBad? 1�8TheValueofRemnantPatches 1�9Lessons 1�9
Chapter 8. Wildlife Restoration: A Synthesis 187MajorMessages 188DevelopingaRestorationPlan 190InformationGaps 19�WorkingwithWildlifeScientistsandManagers 19�Lessons 19�
Index 199
9� Wildlife Restoration
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From chapter 1, “Populations”
Three Roads to Recovery: Breeding, Reintroduction, and Translocation
Althoughhabitatrestorationistheprimaryfocusofthisbook,inthissectionIreviewtheuseofcaptivebreeding,reintroduction,andtranslocationinrestor-inganimalpopulations.Throughouttheworld,thesetechniqueshavebeenusedtoassistwiththerestora-tionofnumerousrareandendangeredspecies.Thegoal of this section is to introduce readers to thesethreeoptionsforrestorationprograms.Theprocessof restorationoftencreatesa systemofsubdivided populations of animals. Metapopulationbiology,therefore,hasdirectapplicationtothedesignandmanagementofrestorationprojects.Metapopu-lationdynamicsincludeslocalpopulationextinction,local population establishment or reestablishment,and movement or linkage among the various localpopulations. Metapopulation management, if prop-erlyapplied,canreducetheprobabilityofpermanentextinctioninlocalpopulationsandhelpmaintainge-neticvariability.Captivebreedingfacilitiescanmain-tainessentiallyfragmentedpopulations.Thuscaptivepropagation and restoration planning depend on aknowledgeofmetapopulationdynamics(BowlesandWhelan199�).Captivebreedingandreintroductionarenottheide-almeansof achieving recoveryof rarepopulations.Captive propagation is expensive, and reintroduc-
tionisproblematic.Factorssuchasratesofgeneflowamong subpopulations, effective population size,mutationrates,andsocialstructuremustallbecon-sidered when planning restoration and reintroduc-tion. Small populations might have been subject topast population bottlenecks, and genetic manipula-tionmightberequiredtorecoverdecliningpopula-tionsortorestoreormaintainevolutionarypotential.Maintenance of genetic variation and evolutionarypotential are concerns for rare or isolated popula-tionsaswellascaptivepopulations.Captivebreedingmayleadtolossofgeneticvariationthroughrandomdrift, togeneticadaptation throughselection to thecaptiveenvironment,andthustoinadequateadapta-tionforreintroductiontoarestoredlocation(BowlesandWhelan199�).Rameyetal.(�000)citefivekeyissuesyoumustad-dresswhenconsideringtheaugmentationofpopula-tions:ß Aretheretwolinesofevidence(genetic,demo-
graphic,behavior)supportingthehypothesesthataseverepopulationbottleneckhasoccurred?
About This Excerpt
Inthispracticalbook,theinauguralvolumeoftheScience and Practice of Ecological Restorationseries,MichaelL.Morrisonprovidesecologists,restorationists, managers, and students witha basic understanding of the fundamentals ofwildlife populations and wildlife/habitat rela-tionships. He argues that the success of a res-torationprojectshouldbejudgedbyhowwild-life species respond to it. In this excerpt fromchapter1,Morrisondiscussesthreeavenuestorecoveryofwildlifepopulations.
Figure 1.5: Chronology of a captive breeding and restoration program. (From Mace et al. (eds.), “Conserving Genetic Diversity with the Help of Biotechnology—Desert Antelopes as an Example,” Figure 1. Pages 123–134 in H. D. M. Moore et al. (eds.), Biotechnology and the Conser-vation of Genetic Diversity. Copyright 1992, The Zoological Society of London. (Reprinted by permission of Oxford University Press.)
9�Chapter 1: Populations
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ß Wouldtheintroductionofadditionalanimalsde-graderesourceconditions,drivingthewildani-malstomorerapidextinction?
ß Was thepopulationbottleneckdue toadiseaseoutbreak(orotherspecificoccurrence)andcanyoueliminatethesourceoftheproblem?
ß Are there habitat patches nearby to establish apopulation (or metapopulation) of larger sizeratherthanasingle,isolatedpopulation?
ß Howshould the sexandagecompositionofanaugmentationbestructured?
Thesequestionsmustbeconsideredbeforeyoubeginananimalrestorationproject.Moreover,thereisnoreasontoproceedwithreintroductionifhabitatandnicheconditionsarenotappropriate.
Issues
Captivebreedingandreintroductionhavebeensuc-cessful and indeed may be the only alternative toextinction in the wild. A restoration and conserva-tionprogramthatincludescaptivebreedingandre-introduction involves numerous overlapping steps(Figure 1.�). Here I review some of the issues youshouldconsiderwhenplanningforcaptivebreeding,reintroduction,ortranslocation.IdrawheavilyfromthesummaryofgeneticconsiderationsdiscussedbyLacy(199�).GOALS.Thegoalofcaptivebreedingprogramsistosupportsurvivalof thespecies,subspecies,orotherdefinedunitinthewild.AccordingtoDeBoer(199�),meetingthisgoalrequires:ß Propagating and managing highly endangered
taxa, with prescribed levels of genetic diversityand demographic stability, for defined periodsof time, to prevent extinction. Using captiveprogramsaspartofconservationstrategiesthatmanage captive and wild populations to ensuresurvivalofthesetaxainthewild—whichmeansusing captive populations to reestablish, rein-force,orre-createwildpopulations.
ß Developingself-sustainingcaptivepopulationsofrareorendangeredtaxaforeducationprogramsthat benefit the survival of conspecifics in thewild(Figure1.�).
Regardlessofthespecies,therearecertainprerequi-sitestomeetingthesegoals:ß Attheleveloftheindividual,sufficientlongev-
ityandphysical,physiological,andpsycholog-icalwell-beingshouldbeassuredinthecaptivesituation. This involves species-specific zoo-technical, medical, and biological knowledgeandresearch.
ß Atthelevelofbreedingpairsandgroups,suffi-cientreproductionshouldbeassuredtoguar-anteecontinuityovergenerations.Thisentailsspecies-specificknowledgeandresearchonre-productivebiology,ethology,andrelatedtop-ics.
ß Atthelevelofpopulation,thepreservationofageneticpopulationstructureshouldbeassuredthatresembles thewildoneascloselyaspos-sible.
Excerpted from Wildlife Restoration by Michael L. Morrison. Copyright © 2002 by Island Press. Excerpted by permission of Island Press. All rights reserved. No part of this excerpt may be reproduced or reprinted without permission in writing from the publisher. Island Press grants permission to forward this unaltered electronic document to friends, colleagues, and other interested parties.
Figure 1.6: The Hawaiian goose, or nene, is being raised at the Zoologi-cal Society of San Diego’s Keauhou Bird Center, Hawaii, for reintroduc-tion into the wild. (Photo courtesy of Zoological Society of San Diego.)
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