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Arctic Shifts to a Carbon Source due to Winter Soil Emissions

A NASA-funded study suggests winter carbon emissions in the Arctic may be adding more carbon into the atmosphere each year than is taken up by Arctic vegetation, marking a stark reversal for a region that has captured and stored carbon for tens of thousands of years.

An airborne view of Arctic tundra, with grass and short scrub brush covering most of the ground and thin rivers and small lakes dotting the landscape.
The Active Sensing of Carbon Emissions over Nights, Days and Seasons (ASCENDS) campaign flew over Nome, Alaska, on August 5, 2017, as part of NASA’s Arctic Boreal Vulnerability Experiment (ABoVE).
Credits: NASA

The study, published Oct. 21 in Nature Climate Change, warns that winter carbon dioxide loss from the world’s permafrost regions could increase by 41% over the next century if human-caused greenhouse gas emissions continue at their current pace. Carbon emitted from thawing permafrost has not been included in the majority of models used to predict future climates.

Permafrost is the carbon-rich frozen soil that covers 24% of Northern Hemisphere land area, encompassing vast stretches of territory across Alaska, Canada, Siberia and Greenland. Permafrost holds more carbon than has ever been released by humans via fossil fuel combustion, and this permafrost has kept carbon safely locked away in an icy embrace for tens of thousands of years. But as global temperatures warm, permafrost is thawing and releasing greenhouse gases to the atmosphere.

“These findings indicate that winter carbon dioxide loss may already be offsetting growing season carbon uptake, and these losses will increase as the climate continues to warm,” said Woods Hole Research Center Arctic Program Director Sue Natali, lead author of the study. “Studies focused on individual sites have seen this transition, but until now we haven’t had a clear accounting of the winter carbon balance throughout the entire Arctic region.”

The side of a hillside that has fallen away to reveal a slippery muddy surface.
A deep cut into an Alaskan hillside reveals thousands of years-old permafrost, often called the “fossilized glaciers” of the cryosphere.
Credits: NASA/Jefferson Beck

This study was supported by NASA’s Arctic-Boreal Vulnerability Experiment  (ABoVE) and conducted in coordination with the Permafrost Carbon Network and more than 50 collaborating institutions. In addition to space-based observations of Earth’s changing environment, NASA sponsors scientific field campaigns to advance our understanding of how our climate is changing and could change in the future.

Researchers compiled on-the-ground observations of carbon dioxide emissions across many sites and combined these with remote sensing data and ecosystem models to assess current and future carbon losses during winter for northern permafrost regions. They estimate a yearly loss of 1.7 billion metric tons of carbon from the permafrost region during the winter season from 2003 to 2017 compared to the estimated average of 1 billion metric tons of carbon taken up during the growing season.

To extend model predictions to warmer conditions in 2100, the climate predicted for different scenarios of future fossil fuel emissions were used to calculate the effect on permafrost. If fossil fuel use is modestly reduced over the next century, winter carbon dioxide emissions would increase 17% compared with current emissions. Under a scenario where fossil fuel use continues to increase at current rates through the middle of the century, winter carbon dioxide emissions from permafrost would rise by 41%.

“The warmer it gets, the more carbon will be released into the atmosphere from the permafrost region, which will add to further warming,” said co-author Brendan Rogers, a climate scientist at the Woods Hole Research Center. “It’s concerning that our study, which used many more observations than ever before, indicates a much stronger Arctic carbon source in the winter. We may be witnessing a transition from an annual Arctic carbon sink to a carbon source, which is not good news.”

Climate modeling teams across the globe are trying to incorporate processes and dynamic events that influence permafrost’s carbon emissions. For example, thermokarst lakes formed by melting ice can speed up the rate of carbon dioxide emissions by exposing deeper layers of permafrost to warmer temperatures. Likewise, Arctic and boreal forest fires, which are becoming more frequent and severe, can remove the insulating top layer of soil, accelerating and deepening permafrost thaw.

“Those interactions are still not accounted for in most of the models and will undoubtedly increase estimates of carbon emissions from permafrost regions,” Rogers said.

For more information on NASA Earth Science:

https://www.nasa.gov/earth

By: Samson Reiny

NASA’s Earth Science News Team