A pan-Arctic synthesis of CH4 and CO2 production from anoxic soil incubations

Authors

Claire C. Treat, University of New Hampshire, Durham
Susan M. Natali, Woods Hole Research Center
Jessica G. Ernakovich, University of New Hampshire, DurhamFollow
Colleen M. Iversen, Oak Ridge National Laboratory
Massimo Lupascu, University of California, Irvine
Anthony David McGuire, University of Alaska Fairbanks
Richard J. Norby, Oak Ridge National Laboratory
Taniya Roy Chowdhury, Oak Ridge National Laboratory
Andreas Richter, University of Vienna
Hana Santruckova, University of South Bohemia
Christina Schadel, University of Florida
Edward A. G. Schuur, University of Florida
Victoria L. Sloan, Oak Ridge National Laboratory
Merritt R. Turestsky, University of Guelph
Mark P. Waldrop, U.S. Geological Survey

Abstract

Permafrost thaw can alter the soil environment through changes in soil moisture, frequently resulting in soil saturation, a shift to anaerobic decomposition, and changes in the plant community. These changes, along with thawing of previously frozen organic material, can alter the form and magnitude of greenhouse gas production from permafrost ecosystems. We synthesized existing methane (CH4) and carbon dioxide (CO2) production measurements from anaerobic incubations of boreal and tundra soils from the geographic permafrost region to evaluate large-scale controls of anaerobic CO2 and CH4 production and compare the relative importance of landscape-level factors (e.g., vegetation type and landscape position), soil properties (e.g., pH, depth, and soil type), and soil environmental conditions (e.g., temperature and relative water table position). We found fivefold higher maximum CH4 production per gram soil carbon from organic soils than mineral soils. Maximum CH4 production from soils in the active layer (ground that thaws and refreezes annually) was nearly four times that of permafrost per gram soil carbon, and CH4 production per gram soil carbon was two times greater from sites without permafrost than sites with permafrost. Maximum CH4 and median anaerobic CO2 production decreased with depth, while CO2:CH4 production increased with depth. Maximum CH4 production was highest in soils with herbaceous vegetation and soils that were either consistently or periodically inundated. This synthesis identifies the need to consider biome, landscape position, and vascular/moss vegetation types when modeling CH4 production in permafrost ecosystems and suggests the need for longer-term anaerobic incubations to fully capture CH4 dynamics. Our results demonstrate that as climate warms in arctic and boreal regions, rates of anaerobic CO2 and CH4 production will increase, not only as a result of increased temperature, but also from shifts in vegetation and increased ground saturation that will accompany permafrost thaw.

Department

Soil Biogeochemistry and Microbial Ecology

Publication Date

1-24-2015

Journal Title

Global Change Biology

Publisher

Wiley

Digital Object Identifier (DOI)

https://dx.doi.org/10.1111/gcb.12875

Document Type

Article

Recommended Citation

Treat, C.C., Natali, S.M., Ernakovich, J., Iversen, C.M., Lupascu, M., McGuire, A.D., Norby, R.J., Roy Chowdhury, T., Richter, A., Šantrůčková, H., Schädel, C., Schuur, E.A.G., Sloan, V.L., Turetsky, M.R. and Waldrop, M.P. (2015), A pan-Arctic synthesis of CH4 and CO2 production from anoxic soil incubations. Glob Change Biol, 21: 2787-2803. https://doi.org/10.1111/gcb.12875

Rights

© 2015 John Wiley & Sons Ltd

Comments

This is an Author Manuscript of an article published by Wiley in Global Change Biology, the Version of Record is available online: https://dx.doi.org/10.1111/gcb.12875