“Twenty years ago there was very little research about the possible rate of permafrost carbon release,” said co-author A. David McGuire, U.S. Geological Survey senior scientist and climate modeling expert with the Institute of Arctic Biology at the University of Alaska Fairbanks. “In 2011, we assembled an international team of scientists into the Permafrost Carbon Network to synthesize existing research and answer the questions of how much permafrost carbon is out there, how vulnerable to decomposition it is once it’s thawed, and what are the forms in which it’s released into the atmosphere.”
Permafrost soils contain twice as much carbon as there is currently in the atmosphere. As the climate warms and permafrost thaws, microbial breakdown of organic carbon increases and can accelerate the release of carbon dioxide and methane into the atmosphere creating even more warming. In high-latitude regions of the Earth, temperatures have risen 0.6 C per decade during the last thirty years — twice as fast as the global average.
Permafrost has warmed nearly 11 degrees F in the past 30 years, according to co-author Vladimir Romanovsky, a permafrost expert with the UAF Geophysical Institute. In the 1980s, the temperature of permafrost in Alaska, Russia and other Arctic regions averaged to be almost 18 F. Now the average is just over 28 F.
Two decades ago, scientists thought that as permafrost thawed, carbon would be released in a big “bomb” and significantly accelerate climate warming.
“The data from our team’s syntheses don’t support the permafrost carbon bomb view,” said McGuire. “What our syntheses do show is that permafrost carbon is likely to be released in a gradual and prolonged manner, and that the rate of release through 2100 is likely to be of the same order as the current rate of tropical deforestation in terms of its effects on the carbon cycle.”
Most climate modelers want to incorporate the permafrost carbon feedback into their models, say these scientists, but whether they do or don’t is a matter of their priorities given the multitude of issues that such models must consider. McGuire, Romanovsky and their co-authors consider the synthesis very important information for climate models in setting their priorities.
“If society’s goal is to try to keep the rise in global temperatures under two degrees C and we haven’t taken permafrost carbon release into account in terms of mitigation efforts, then we might underestimate that amount of mitigation effort required to reach that goal,” McGuire said.
Scientists in the Permafrost Carbon Network plan to continue to help the modeling community make refinement to improve representation of permafrost carbon and its fate in a warming world. They recommend improved observation networks, including remote sensing capabilities to quantify real-time carbon dioxide and methane emissions from permafrost regions.
Reference: E. A. G. Schuur, A. D. McGuire, C. Schädel, G. Grosse, J. W. Harden, D. J. Hayes, G. Hugelius, C. D. Koven, P. Kuhry, D. M. Lawrence, S. M. Natali, D. Olefeldt, V. E. Romanovsky, K. Schaefer, M. R. Turetsky, C. C. Treat, J. E. Vonk. Climate change and the permafrost carbon feedback. Nature, 2015; 520 (7546): 171 DOI: 10.1038/nature14338