The impact of the permafrost carbon feedback on global climate

Schaefer, Kevin; Lantuit, Hugues; Romanovsky, V. E.; Schuur, Edward A. G.; Witt, Ronald G.

doi:10.1088/1748-9326/9/8/085003

Cited by 326 publications

(272 citation statements)

References 52 publications

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“…Several studies have proposed that DOC components are more labile than POC, as the DOC contributed from permafrost was possibly unprocessed before mobilization and consisted predominantly of labile low-molecular-weight and few aromatic compounds Waldrop et al, 2010). This degradation process most likely causes the formation of greenhouse gases (Schaefer et al, 2014;Schuur et al, 2015). Knoblauch et al (2013) showed that the highest OM mineralization rates and CO 2 production were found directly after permafrost thaw and projected a loss of initial OC of 15% within 100 years.…”

Section: Processes After Initial Slumpingmentioning

confidence: 99%

“…That leads to increased greenhouse gas emissions and, ultimately, climate warming -a process known as the permafrost carbon feedback. However, due to the complexity of environmental processes, the intensity of this feedback remains unclear (Schaefer et al, 2014;Schuur et al, 2015). Besides being released as greenhouse gases, OM can be redeposited on land or transported to aquatic systems where it can be further mineralized in the water column or buried in sediments (Cory et al, 2013;Letscher et al, 2011;Vonk et al, 2014;Woods et al, 2011).…”

Section: Introductionmentioning

confidence: 99%

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Transformation of terrestrial organic matter along thermokarst-affected permafrost coasts in the Arctic

Tanski

Lantuit

Ruttor

et al. 2017

Science of The Total Environment

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Section: Processes After Initial Slumpingmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Transformation of terrestrial organic matter along thermokarst-affected permafrost coasts in the Arctic

Tanski

Lantuit

Ruttor

et al. 2017

Science of The Total Environment

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“…Yedoma deposits formed during the late Pleistocene cold stages in unglaciated Beringia and are characterized by high ice contents, fine grain size, and a good preservation of organic carbon . As the terrestrial Arctic warms up, permafrost soils, including those located in IWPs in drained lake basins, are expected to release substantial greenhouse gas emissions that will generate a positive feedback to global warming (Dutta et al, 2006;Koven et al, 2011;Schaefer et al, 2014). Walter Anthony et al (2014) indicated that widespread permafrost thaw could ultimately result in reduced lake and wetland abundance caused by drainage and drying, facilitating rapid decomposition of freeze-locked organic matter.…”

Section: Introductionmentioning

confidence: 99%

Holocene ice-wedge polygon development in northern Yukon permafrost peatlands (Canada)

Fritz

Wolter

Rudaya

et al. 2016

Quaternary Science Reviews

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a b s t r a c tIce-wedge polygon (IWP) peatlands in the Arctic and Subarctic are extremely vulnerable to climatic and environmental change. We present the results of a multidisciplinary paleoenvironmental study on IWPs in the northern Yukon, Canada. High-resolution laboratory analyses were carried out on a permafrost core and the overlying seasonally thawed (active) layer, from an IWP located in a drained lake basin on Herschel Island. In relation to 14 Accelerator Mass Spectrometry (AMS) radiocarbon dates spanning the last 5000 years, we report sedimentary data including grain size distribution and biogeochemical parameters (organic carbon, nitrogen, C/N ratio, d 13 C), stable water isotopes (d 18 O, dD), as well as fossil pollen, plant macrofossil and diatom assemblages. Three sediment units (SUs) correspond to the main stages of deposition (1) in a thermokarst lake (SU1: 4950 to 3950 cal yrs BP), (2) during transition from lacustrine to palustrine conditions after lake drainage (SU2: 3950 to 3120 cal yrs BP), and (3) in palustrine conditions of the IWP field that developed after drainage (SU3: 3120 cal yrs BP to 2012 CE). The lacustrine phase (pre 3950 cal yrs BP) is characterized by planktonic-benthic and pioneer diatom species indicating circumneutral waters, and very few plant macrofossils. The pollen record has captured a regional signal of relatively stable vegetation composition and climate for the lacustrine stage of the record until 3950 cal yrs BP. Palustrine conditions with benthic and acidophilic diatom species characterize the peaty shallow-water environments of the low-centered IWP. The transition from lacustrine to palustrine conditions was accompanied by acidification and rapid revegetation of the lake bottom within about 100 years. Since the palustrine phase we consider the pollen record as a local vegetation proxy dominated by the plant communities growing in the IWP. Ice-wedge cracking in water-saturated sediments started immediately after lake drainage at about 3950 cal yrs BP and led to the formation of an IWP mire. Permafrost aggradation through downward closed-system freezing of the lake talik is indicated by the stable water isotope record. The originally submerged IWP center underwent gradual drying during the past 2000 years. This study highlights the sensitivity of permafrost landscapes to climate and environmental change throughout the Holocene.

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“…This will have a wide variety of ecosystem effects (Alexander and Mack, 2016): in particular, rising temperatures and increasing fire will likely result in changes in soil temperature and permafrost degradation (Pastick et al, 2015;Zhang et al, 2015;Genet et al, 2013;Helbig et al, 2016), with subsequent hydrology changes that will influence soil greenhouse gas (GHG) fluxes to the atmosphere (Schädel et al, 2014). Such fluxes are a large component of the global C cycle and could result in a significant and positive climate feedback Koven et al, 2011;Schaefer et al, 2014).…”

Section: Introductionmentioning

confidence: 99%

Temperature and moisture effects on greenhouse gas emissions from deep active-layer boreal soils

2016

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Abstract. Rapid climatic changes, rising air temperatures, and increased fires are expected to drive permafrost degradation and alter soil carbon (C) cycling in many high-latitude ecosystems. How these soils will respond to changes in their temperature, moisture, and overlying vegetation is uncertain but critical to understand given the large soil C stocks in these regions. We used a laboratory experiment to examine how temperature and moisture control CO 2 and CH 4 emissions from mineral soils sampled from the bottom of the annual active layer, i.e., directly above permafrost, in an Alaskan boreal forest. Gas emissions from 30 cores, subjected to two temperatures and either field moisture conditions or experimental drought, were tracked over a 100-day incubation; we also measured a variety of physical and chemical characteristics of the cores. Gravimetric water content was 0.31 ± 0.12 (unitless) at the beginning of the incubation; cores at field moisture were unchanged at the end, but drought cores had declined to 0.06 ± 0.04. Daily CO 2 fluxes were positively correlated with incubation chamber temperature, core water content, and percent soil nitrogen. They also had a temperature sensitivity (Q 10 ) of 1.3 and 1.9 for the field moisture and drought treatments, respectively. Daily CH 4 emissions were most strongly correlated with percent nitrogen, but neither temperature nor water content was a significant first-order predictor of CH 4 fluxes. The cumulative production of C from CO 2 was over 6 orders of magnitude higher than that from CH 4 ; cumulative CO 2 was correlated with incubation temperature and moisture treatment, with drought cores producing 52-73 % lower C. Cumulative CH 4 production was unaffected by any treatment. These results suggest that deep active-layer soils may be sensitive to changes in soil moisture under aerobic conditions, a critical factor as discontinuous permafrost thaws in interior Alaska. Deep but unfrozen high-latitude soils have been shown to be strongly affected by long-term experimental warming, and these results provide insight into their future dynamics and feedback potential with future climate change.

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The impact of the permafrost carbon feedback on global climate

Cited by 326 publications

References 52 publications

Transformation of terrestrial organic matter along thermokarst-affected permafrost coasts in the Arctic

Transformation of terrestrial organic matter along thermokarst-affected permafrost coasts in the Arctic

Holocene ice-wedge polygon development in northern Yukon permafrost peatlands (Canada)

Temperature and moisture effects on greenhouse gas emissions from deep active-layer boreal soils

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