Potential carbon emissions dominated by carbon dioxide from thawed permafrost soils

Authors

Christina Sch'del, Northern Arizona University
Martin K.F. Bader, SCION
Edward A.G. Schuur, Northern Arizona University
Christina Biasi, Itä-Suomen yliopisto
Rosvel Bracho, University of Florida
Petr Capek, Jihoceská Univerzita v Ceských Budejovicích
Sarah De Baets, University of Exeter
Katerina Diáková, Jihoceská Univerzita v Ceských Budejovicích
Jessica Ernakovich, CSIRO Agriculture
Cristian Estop-Aragones, University of Exeter
David E. Graham, Oak Ridge National Laboratory
Iain P. Hartley, University of Exeter
Colleen M. Iversen, ORNL Environmental Sciences Division
Evan Kane, Michigan Technological University
Christian Knoblauch, Universität Hamburg
Massimo Lupascu, National University of Singapore
Pertti J. Martikainen, Itä-Suomen yliopisto
Susan M. Natali, Woods Hole Research Center
Richard J. Norby, ORNL Environmental Sciences Division
Jonathan A. O'Donnell, US National Park Service
Taniya Roy Chowdhury, Oak Ridge National Laboratory
Hana Šantrucková, Jihoceská Univerzita v Ceských Budejovicích
Gaius Shaver, Marine Biological Laboratory
Victoria L. Sloan, ORNL Environmental Sciences Division
Claire C. Treat, University of Alaska Fairbanks
Merritt R. Turetsky, University of Guelph
Mark P. Waldro, United States Geological Survey Western Region
Kimberly P. Wickland, United States Geological Survey

Document Type

Article

Publication Date

9-28-2016

Abstract

© 2016 Macmillan Publishers Limited, part of Springer Nature. Increasing temperatures in northern high latitudes are causing permafrost to thaw, making large amounts of previously frozen organic matter vulnerable to microbial decomposition. Permafrost thaw also creates a fragmented landscape of drier and wetter soil conditions that determine the amount and form (carbon dioxide (CO2), or methane (CH 4)) of carbon (C) released to the atmosphere. The rate and form of C release control the magnitude of the permafrost C feedback, so their relative contribution with a warming climate remains unclear. We quantified the effect of increasing temperature and changes from aerobic to anaerobic soil conditions using 25 soil incubation studies from the permafrost zone. Here we show, using two separate meta-analyses, that a 10 °C increase in incubation temperature increased C release by a factor of 2.0 (95% confidence interval (CI), 1.8 to 2.2). Under aerobic incubation conditions, soils released 3.4 (95% CI, 2.2 to 5.2) times more C than under anaerobic conditions. Even when accounting for the higher heat trapping capacity of CH 4, soils released 2.3 (95% CI, 1.5 to 3.4) times more C under aerobic conditions. These results imply that permafrost ecosystems thawing under aerobic conditions and releasing CO2 will strengthen the permafrost C feedback more than waterlogged systems releasing CO2 and CH 4 for a given amount of C.

Publication Title

Nature Climate Change

Recommended Citation

Sch'del, C., Bader, M., Schuur, E., Biasi, C., Bracho, R., Capek, P., De Baets, S., Diáková, K., Ernakovich, J., Estop-Aragones, C., Graham, D., Hartley, I., Iversen, C., Kane, E., Knoblauch, C., Lupascu, M., Martikainen, P., Natali, S., Norby, R., O'Donnell, J., Chowdhury, T., Šantrucková, H., Shaver, G., Sloan, V., Treat, C., Turetsky, M., Waldro, M., & Wickland, K. (2016). Potential carbon emissions dominated by carbon dioxide from thawed permafrost soils. Nature Climate Change, 6(10), 950-953. http://doi.org/10.1038/nclimate3054
Retrieved from: https://digitalcommons.mtu.edu/michigantech-p/8421