List of Credits

Page 25, Fig. 3 – Adapted with kind permission from the Scandinavian Journal ofForest Research.

Page 34, Fig. 5A – From the Canadian Journal of Forest Research. Adapted with kindpermission from NRC Research Press.

Page 34, Fig. 5B – From Ann. Forest Science. Adapted with kind permission fromEDP Sciences.

Page 39, Table 4 – From Global Ecology and Biogeography. Adapted with kindpermission from Blackwell Publishing.

Page 41, Table 5 – From Global Ecology and Biogeography. Adapted with kindpermission from Blackwell Publishing.

Page 42, Fig. 6 – From Global Ecology and Biogeography. Adapted with kindpermission from Blackwell Publishing.

Page 54, Fig. 12 – From Acta Oecologia. Adapted with kind permission from Else-vier.

Page 57, Fig. 13 – Adapted with kind permission from NRC Research Press.Page 61, Table 11 – From Acta Oecologia. Adapted with kind permission fromElsevier.

Page 68, Table 12 – From Water, Air, and Soil Pollution. With kind permission ofSpringer Science and Business Media.

Page 76, Table 1 – From Plant Litter. Decomposition, Humus Formation, and CarbonSequestration. With kind permission of Springer Science and Business Media.

Page 80, Fig. 2 – Adapted with kind permission from Blackwell Publishing.Page 84, Fig. 4 – From Series in Wood Science. With kind permission of SpringerScience and Business Media.

Page 85, Table 2 – From Plant Litter. Decomposition, Humus Formation, and CarbonSequestration. With kind permission of Springer Science and Business Media.

Pages 88–89, Fig. 5 – With kind permission of Taylor & Francis (Marcel Dekker).From Kirk, T.K. (1984) Degradation of lignin. In: Microbial Degradationof Organic Compounds (Ed. by D.T. Gibson), pp. 399–437. Marcel Dekker,New York.

Page 90, Table 3 – From Series in Wood Science. With kind permission of SpringerScience and Business Media.

Page 98, Table 4 – From Applied Soil Ecology. Adapted with kind permission fromElsevier.

Page 103, Fig. 1 – From Environmental Reviews. Adapted with kind permission fromNRC Research Press.

Page 105, Fig. 2 – From the Canadian Journal of Botany. Adapted with kindpermission from NRC Research Press.

Page 110, Fig. 4 – From the Canadian Journal of Botany. Adapted with kindpermission from NRC Research Press.

Page 120, Fig. 7 – From Ecological Bulletins (Stockholm). Adapted with kindpermission from Blackwell Publishing.

LIST OF CREDITS

Page 123, Fig. 8 – Adapted with kind permission from the Scandinavian Journal ofForest Research.

Page 126, Table 3a – From Plant Litter. Decomposition, Humus Formation, andCarbon Sequestration. With kind permission of Springer Science and BusinessMedia.

Page 132, Fig. 10 – From the Canadian Journal of Botany. Adapted with kindpermission from NRC Research Press.

Page 135, Fig. 11 – From Plant Litter. Decomposition, Humus Formation, and CarbonSequestration. With kind permission of Springer Science and Business Media.

Page 136, Fig. 12 – Adapted with kind permission from the Scandinavian Journal ofForest Research.

Page 137, Fig. 13 – Adapted with kind permission from the Scandinavian Journal ofForest Research.

Page 140, Table 6 – From the Canadian Journal of Forest Research. Adapted withkind permission from NRC Research Press.

Page 141, Fig. 14 – From the Canadian Journal of Forest Research. Adapted withkind permission from NRC Research Press.

Page 144, Table 7a – Adapted with kind permission from the Scandinavian Journal ofForest Research.

Page 144, Table 7b – Adapted with kind permission from NRC Research Press.Page 147, Fig. 16 – From Forest Ecology and Management. Adapted with kind

permission from Elsevier.Page 149, Table 9 – From Oecologia Plantarum. Adapted with kind permission from

Elsevier.Page 161, Fig. 2 – From Ecological Bulletins (Stockholm). Adapted with kind

permission from Blackwell Publishing.Page 162, Fig. 3 – From Ecological Bulletins (Stockholm). Adapted with kind

permission from Blackwell Publishing.Page 163, Fig. 4 – From the Canadian Journal of Botany. Adapted with kind

permission from NRC Research Press.Page 166, Table 2 – From Ecological Bulletins (Stockholm). Adapted with kind

permission from Blackwell Publishing.Page 167, Fig. 5 – From the Canadian Journal of Botany. Adapted with kind

permission from NRC Research Press.Page 169, Fig. 6 – From Pedobiologia. Adapted with kind permission from Elsevier.Page 173, Fig. 7 – From the Canadian Journal of Botany. Adapted with kind

permission from NRC Research Press.Page 174, Fig. 8 – From the Canadian Journal of Botany. Adapted with kind

permission from NRC Research Press.Page 177, Fig. 10 – From the Canadian Journal of Botany. Adapted with kind

permission from NRC Research Press.Page 180, Fig. 12 – Adapted with kind permission from the Scandinavian Journal of

Forest Research.Page 183, Fig. 13 – From the Canadian Journal of Botany. Adapted with kind

permission from NRC Research Press.Page 190, Fig. 1 – Adapted with kind permission from John Wiley & Sons, Ltd.Page 199, Table 1 – From Geoderma. Adapted with kind permission from Elsevier.Page 206, Table 3 – From Water, Air, and Soil Pollution. With kind permission of

Springer Science and Business Media.Page 220, Table 5 – From Water, Air, and Soil Pollution. With kind permission of

Springer Science and Business Media.

LIST OF CREDITS

Page 224, Table 6 – From Water, Air, and Soil Pollution. With kind permission ofSpringer Science and Business Media.

Page 230, Fig. 1 – From Plant Litter. Decomposition, Humus Formation, and CarbonSequestration. With kind permission of Springer Science and Business Media.

Page 236, Fig. 3 – From Biogeochemistry. With kind permission of Springer Scienceand Business Media.

Page 237, Fig. 4 – From Biogeochemistry. With kind permission of Springer Scienceand Business Media.

Page 238, Table 5 – From Biogeochemistry. With kind permission of Springer Scienceand Business Media.

Page 242, Fig. 5 – From Biogeochemistry. With kind permission of Springer Scienceand Business Media.

Page 243, Fig. 6 – From the Canadian Journal of Botany. Adapted with kindpermission from NRC Research Press.

Page 244, Fig. 7 – From the Canadian Journal of Botany. Adapted with kindpermission from NRC Research Press.

Page 246, Table 8 – From the Canadian Journal of Botany. Adapted with kindpermission from NRC Research Press.

Page 246, Fig. 8 – From Soil Biology and Biochemistry. Adapted with kind permissionfrom Elsevier.

Page 248, Table 9 – From Biogeochemistry. With kind permission of Springer Scienceand Business Media.

Page 248, Fig. 9 – From Biogeochemistry. With kind permission of Springer Scienceand Business Media.

Page 249, Table 10 – From Biogeochemistry. With kind permission of SpringerScience and Business Media.

Page 253, Table 12a and b – From the Canadian Journal of Forest Research. Adaptedwith kind permission from NRC Research Press.

Page 255, Fig. 10 – From the Canadian Journal of Forest Research. Adapted withkind permission from NRC Research Press.

Page 257, Fig. 11 – From Environmental Reviews. Adapted with kind permission fromNRC Research Press.

Page 261, Fig. 12 – Adapted with kind permission from the Scandinavian Journal ofForest Research.

Page 270, Table 1 – From Ecology. Adapted with kind permission from the Ecolo-gical Society of America.

Page 271, Fig. 2 – From Ecology. Adapted with kind permission from the EcologicalSociety of America.

Page 274, Fig. 4 – From Ecology. Adapted with kind permission from the EcologicalSociety of America.

Page 277, Fig. 5 – With kind permission of Springer Science and Business Media.Page 279, Fig. 6 – From Ecotoxicology and Environmental Safety. Adapted with kindpermission from Elsevier.

Page 287, Fig. 7 – From Plant and Soil. With kind permission of Springer Science andBusiness Media.

Page 288, Table 2 – From Plant and Soil. With kind permission of Springer Scienceand Business Media.

Page 289, Fig. 8 – From Biogeochemistry. With kind permission of Springer Scienceand Business Media.