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Heat waves thawing Arctic permafrost

Heatwaves thawing Arctic permafrost
Retrogressive thaw slump, Mackenzie River Delta, Canada. Credit: ETH Zurich / Simon Zwieback

In the northernmost region of the earth the arctic permafrost is melting at an accelerated rate. For more than a decade, an international team of researchers from ETH Zurich, the University of Alaska Fairbanks, and the German Aerospace Center have observed topographical pock marks—large depressions referred to as, “retrogressive thaw slumps.” The slumps occur when permanently frozen layers of soil (ice-rich permafrost) melt leaving arctic hillslopes vulnerable to landslides. The landslides signal a risk for the potential release of carbon that has been stored in the permafrost for tens of thousands of years.

Risk for release of organic carbon

Their findings, recently published in the European Geosciences Union journal The Cryosphere, reveal substantial changes to the topography of Siberia’s Taymyr peninsula, in northern Russia. The study’s results reveal a strong, 43-fold increase in retrogressive thaw slump activity and a 28-fold increase in carbon mobilization. The increase also happens to coincide with an extreme heat wave that occurred in northern Siberia in 2020 in which temperatures reportedly reached 38 degrees Celsius (more than 100 degrees Fahrenheit)—record-breaking temperatures for the Arctic region.

“The strong increase in thaw slump activity due to the Siberian heatwave shows that carbon mobilization from permafrost soils can respond sharply and non-linearly to increasing temperatures,” asserts the paper’s lead author, Philipp Bernhard, Institute of Environmental Engineering, ETH Zurich.

Measuring changes to Arctic permafrost

Using satellite data, the research team has been able to develop a new method to quantify carbon mobilization in permafrost soil. Currently no other large-scale method exists that measures, to such a high level of spatial and vertical resolution, the changes in permafrost regions. This method allows researchers to provide a more accurate estimate of the state of the carbon cycle to the global carbon budget.

Building on an earlier field and airborne flight study conducted in Canada’s Mackenzie River Delta, the researchers collected pre-study data that they later used to compare and analyze with satellite acquired data over the same region. Since 2010, the German Aerospace Center has been operating an innovative satellite mission using single-pass synthetic aperture radar, the TanDEM-X mission, to collect 3-dimensional elevation data over the earth surface. In addition to the radar data, from 2015, researchers analyzed data obtained from the optical Sentinel-2 satellites deployed as part of the European Space Agency’s Earth Observation mission, Copernicus Program with the focus on the arctic landscape.

Sentinel-2 satellite elevation comparison of the Taymyr Peninsula in Siberia from Summer 2019 and 2021. The vegetation (red) change due to thaw slumps activity is clearly visible. Credit: European Space Agency (ESA) / ETH Zurich

Neglected part of Arctic carbon cycle

Siberia’s Taymyr peninsula, like many areas of the arctic, is a remote and nearly inaccessible region making scientific field studies a challenging, if not impossible, operation. The findings of this study indicate; however, that summer heatwaves and warming arctic regions pose a significant environmental risk that are worth monitoring.

TanDEM-X radar elevation comparison between 2010—2017 of Mackenzie River Delta, Canada. Credit: ETH Zurich

The Arctic permafrost reportedly encases approximately 1.5 trillion metric tons of organic carbon, about twice as much as currently contained in the atmosphere. Bernhard agrees that the potential risks associated with this type of carbon mobilization is “a major, but largely neglected component of the Arctic carbon cycle.” The research team anticipates that satellite remote sensing will be an indispensable tool for continuous monitoring of carbon mobilization resulting from melting permafrost across the Arctic.


Explore further

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More information:
Philipp Bernhard et al, Accelerated mobilization of organic carbon from retrogressive thaw slumps on the northern Taymyr Peninsula, The Cryosphere (2022). DOI: 10.5194/tc-16-2819-2022

Philipp Bernhard et al, Mapping Retrogressive Thaw Slumps Using Single-Pass TanDEM-X Observations, IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing (2020). DOI: 10.1109/JSTARS.2020.3000648

Journal information:
The Cryosphere


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ETH Zurich


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Heat waves thawing Arctic permafrost (2022, July 28)
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