Dear Deeply Readers,

Welcome to the archives of Arctic Deeply. While we paused regular publication of the site on September 15, 2017, and transitioned some of our coverage to Oceans Deeply, we are happy to serve as an ongoing public resource on the Arctic. We hope you’ll enjoy the reporting and analysis that was produced by our dedicated community of editors contributors.

We continue to produce events and special projects while we explore where the on-site journalism goes next. If you’d like to reach us with feedback or ideas for collaboration you can do so at [email protected].

Warming Arctic Creates GHG Danger Zone

CLIMATE NEWS NETWORK: Researchers warn that thawing soils in the Arctic tundra’s permafrost will release increasing quantities of carbon dioxide and methane into the atmosphere.

Written by Tim Radford Published on Read time Approx. 3 minutes
A new study suggests that as permafrost warms and dries it will release even more carbon dioxide, a powerful greenhouse gas, than previously calculated.National Parks Service

LONDON – Climate scientists have coolly established the mechanism by which a warming Arctic will accelerate the warming of the whole world. It’s simple: As the permafrost warms and dries, it will release ever-greater quantities of carbon dioxide from the Arctic soils.

And those bits of tundra that warm, thaw and become increasingly soggy will release ever greater quantities of methane, a greenhouse gas (GHG) more short-lived but also a far more potent heat trap than CO2.

The impact of the carbon dioxide, they say, could be dominant in accelerating global climate change. Since the Arctic region is already the fastest-warming place on the planet, and since the soils of the permafrost are calculated to hold twice as much carbon as is already in the atmosphere, the stakes are high – and so is the pressure on climate scientists to get the details right.

Christina Schadel, an ecosystem scientist at Northern Arizona University in the U.S., and 23 colleagues from New Zealand, Finland, the Czech Republic, the U.K., Australia, Canada, Germany, Singapore and other U.S. institutions report in Nature Climate Change that they made a meta-analysis of 25 separate incubation experiments with soils from the permafrost zone to establish the fine detail of what happens when long-frozen soil is warmed by 10C (18F).

Carbon Feedback

They found that temperature and moisture both mattered – and the biggest delivery of potential greenhouse warming came with the mix of microbes, soil carbon and oxygen.

“Our results show that increasing temperatures have a large effect on carbon release from permafrost, but that changes in soil moisture conditions have an even greater effect,” Dr. Schadel says. “We conclude that the permafrost carbon feedback will be stronger when a larger percentage of the permafrost zone undergoes thaw in a dry and oxygen-rich environment.”

That a thawing Arctic could, just by the act of thawing, still further accelerate climate change is not news. Researchers have not just repeatedly confirmed the hazard but have even tried to estimate the future toll on global economies.

A report in the latest edition of Geophysical Research Letters journal says that even under the shallow lakes that dot the Arctic lowlands, permafrost is beginning to thaw.

Lakebed temperatures at a depth of a 1m (3.3ft) or less have warmed by 2.4C (4.3F) during the last three decades, and for five of the last seven years, the mean annual lakebed temperature has stayed above freezing.

So warming is inexorable − and, with it, the potential release of huge quantities of long-buried carbon preserved in the peat and frozen plant material in the soils.

Question of Topography

The Nature Climate Change study picks apart the fine detail of the process, and the next step is to establish whether thawing polar soils will become wetter or drier overall. This could boil down to a question of topography.

“A few centimeters can make the difference in whether the ground slumps and becomes wetter or ends up high and dry, by separating more from the water table,” says Colleen Iversen, an ecosystem scientist at the Oak Ridge National Laboratory in the U.S. and a coauthor of the report.

“There are also big ponds that might dry out over large areas, as well as soils underlain by a network of ice wedges where warming could lead to a thermokarst, or a slumping, of the land surface as permafrost thaws and the ice wedges melt.

“So the wetting and drying of the Arctic is important to observe and model at scales ranging from a meter to multiple kilometers.”

The views expressed in this article belong to the author and do not necessarily reflect the editorial policy of Arctic Deeply.

A version of this story was first published by the Climate News Network. It is reprinted here with permission.

Suggest your story or issue.


Share Your Story.

Have a story idea? Interested in adding your voice to our growing community?

Learn more