Ecosystem carbon response of an Arctic peatland to simulated permafrost thaw

Voigt, Carolina; Marushchak, Maija E.; Mastepanov, Mikhail; Lamprecht, Richard E.; Christensen, Torben R.; Dorodnikov, Maxim; Jackowicz-Korczyński, Marcin; Lindgren, Amelie; Lohila, Annalea; Nykänen, Hannu; Oinonen, M.; Oksanen, Timo; Palonen, Vesa; Treat, Claire C.; Martikainen, Pertti J.; Biasi, Christina

doi:10.1111/gcb.14574

Cited by 65 publications

(49 citation statements)

References 126 publications

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“…Higher CH 4 oxidation in thawed permafrost versus intact permafrost has also been observed in polygonal tundra (Vaughn et al, 2016) and a peat plateau (Voigt et al, 2019); however, in both cases permafrost thaw led to drier conditions (i.e., less reducing environment). By contrast, our results indicate that more reducing conditions coincide with greater CH 4 oxidation rates.…”

Section: Redox Potential Is a Stronger Predictor Of Methane Oxidationmentioning

confidence: 82%

“…Thus, as permafrost is thawing due to atmospheric warming at a global scale (Olefeldt et al, 2016;Turetsky et al, 2019), it is vital to understand the potential of MOB to attenuate CH 4 emissions from thawing permafrost. Previous work comparing the abundance/activity of MOB using intact and thawed sites (Liebner & Wagner, 2007;Vaughn et al, 2016) or through in vitro experiments thawing permafrost cores (Mackelprang et al, 2011;Voigt et al, 2019) suggests that permafrost thaw can increase CH 4 oxidation. However, these studies focused on comparing end-member thaw states, which omit CH 4 oxidation in transitional thaw stages that can cover a considerable area of thawing permafrost peatlands (Malmer et al, 2005;Palace et al, 2018).…”

Section: Introductionmentioning

confidence: 99%

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Thaw Transitions and Redox Conditions Drive Methane Oxidation in a Permafrost Peatland

et al. 2020

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Permafrost peatlands are a significant source of methane (CH4) emissions to the atmosphere and could emit more CH4 with continued permafrost thaw. Aerobic methane‐oxidizing bacteria may attenuate a substantial fraction of CH4 emissions in thawing permafrost peatlands; however, the impact of permafrost thaw on CH4 oxidation is uncertain. We measured potential CH4 oxidation rates (hereafter, CH4 oxidation) and their predictors using laboratory incubations and in situ porewater redox chemistry across a permafrost thaw gradient of eight thaw stages at Stordalen Mire, a permafrost peatland complex in northernmost Sweden. Methane oxidation rates increased across a gradient of permafrost thaw and differed in transitional thaw stages relative to end‐member stages. Oxidation was consistently higher in submerged fens than in bogs or palsas across a range of CH4 concentrations. We also observed that CH4 oxidation increased with decreasing in situ redox potential and was highest in sites with lower redox potential (Eh < 10 mV) and high water table. Our results suggest that redox potential can be used as an important predictor of CH4 oxidation, especially in thawed permafrost peatlands. Our results also highlight the importance of considering transitional thaw stages when characterizing landscape‐scale CH4 dynamics, because these transitional areas have different rates and controls of CH4 oxidation relative to intact or completely thawed permafrost areas. As permafrost thaw increases the total area of semiwet and wet thaw stages in permafrost peatlands, CH4 oxidation represents an important control on CH4 emissions to the atmosphere.

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Section: Redox Potential Is a Stronger Predictor Of Methane Oxidationmentioning

confidence: 82%

Section: Introductionmentioning

confidence: 99%

Thaw Transitions and Redox Conditions Drive Methane Oxidation in a Permafrost Peatland

et al. 2020

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“…To assess the effect of permafrost thaw on peatland C and N budgets, we distinguish four main potential stages in the longterm transition from stable permafrost to nonpermafrost peatlands ( Fig (45)(46)(47). If thaw progresses into ice-rich permafrost, thermokarst may occur (18).…”

Section: Resultsmentioning

confidence: 99%

“…1) Intact permafrost peatlands are sinks of CO 2 and have near-neutral CH 4 and N 2 O balances ( 41 – 44 ). 2) Gradual active layer warming and deepening cause releases of CO 2 and N 2 O from the active layer and from newly thawed peat while CH 4 remains near neutral ( 45 – 47 ). If thaw progresses into ice-rich permafrost, thermokarst may occur ( 18 ).…”

Section: Resultsmentioning

confidence: 99%

Large stocks of peatland carbon and nitrogen are vulnerable to permafrost thaw

Hugelius

Loisel

Chadburn

et al. 2020

Proc. Natl. Acad. Sci. U.S.A.

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401

403

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Northern peatlands have accumulated large stocks of organic carbon (C) and nitrogen (N), but their spatial distribution and vulnerability to climate warming remain uncertain. Here, we used machine-learning techniques with extensive peat core data (n > 7,000) to create observation-based maps of northern peatland C and N stocks, and to assess their response to warming and permafrost thaw. We estimate that northern peatlands cover 3.7 ± 0.5 million km2 and store 415 ± 150 Pg C and 10 ± 7 Pg N. Nearly half of the peatland area and peat C stocks are permafrost affected. Using modeled global warming stabilization scenarios (from 1.5 to 6 °C warming), we project that the current sink of atmospheric C (0.10 ± 0.02 Pg C⋅y−1) in northern peatlands will shift to a C source as 0.8 to 1.9 million km2 of permafrost-affected peatlands thaw. The projected thaw would cause peatland greenhouse gas emissions equal to ∼1% of anthropogenic radiative forcing in this century. The main forcing is from methane emissions (0.7 to 3 Pg cumulative CH4-C) with smaller carbon dioxide forcing (1 to 2 Pg CO2-C) and minor nitrous oxide losses. We project that initial CO2-C losses reverse after ∼200 y, as warming strengthens peatland C-sinks. We project substantial, but highly uncertain, additional losses of peat into fluvial systems of 10 to 30 Pg C and 0.4 to 0.9 Pg N. The combined gaseous and fluvial peatland C loss estimated here adds 30 to 50% onto previous estimates of permafrost-thaw C losses, with southern permafrost regions being the most vulnerable.

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“…There has been considerable interest in quantifying GHG fluxes from high latitude regions; however, most studies concentrate on CO 2 fluxes (Fahnestock et al 1999;Johnson et al 2000;Hobbie et al 2002;Elberling 2003Elberling , 2007Welker et al 2004;Oberbauer et al 2007;Euskirchen et al 2017). Investigations of CH 4 exchange in Arctic ecosystems have often focused on wetland areas (e.g., Mastepanov et al 2013;Olefeldt et al 2013;Johnston et al 2014;Voigt et al 2019) and found fluxes to be dependent mostly on water table position and soil temperature (Christensen 1993;Torn and Chapin 1993;Rustad et al 2001;Brummell et al 2012;Zona et al 2016;Taylor et al 2018;Voigt et al 2019). In wet sites, aboveground biomass can mediate CH 4 emissions by acting as a conduit for gas exchange between the land and the atmosphere (Torn and Chapin 1993;Wilson and Humphreys 2010).…”

Section: Introductionmentioning

confidence: 99%

Net greenhouse gas fluxes from three High Arctic plant communities along a moisture gradient

et al. 2019

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Climate in high latitude environments is predicted to undergo a pronounced warming and increase in precipitation, which may influence the terrestrial moisture gradients that affect vegetation distribution. Vegetation cover can influence rates of greenhouse gas production through differences in microbial communities, plant carbon uptake potential, and root transport of gases out of the soil into the atmosphere. To predict future changes in greenhouse gas production from High Arctic ecosystems in response to climate change, it is important to understand the interaction between trace gas fluxes and vegetation cover. During the growing seasons of 2008 and 2009, we used dark static chambers to measure CH4 and N2O fluxes and CO2 emissions at Cape Bounty, Melville Island, NU, across a soil moisture gradient, as reflected by their vegetation cover. In both years, wet sedge had the highest rates of emission for all trace gases, followed by the mesic tundra ecosystem. CH4 consumption was highest in the polar semi-desert, correlating positively with temperature and negatively with moisture. Our findings demonstrate that net CH4 uptake may be largely underestimated across the Arctic due to sampling bias towards wetlands. Overall, greenhouse gas flux responses vary depending on different environmental drivers, and the role of vegetation cover needs to be considered in predicting the trajectory of greenhouse gas uptake and release in response to a changing climate.

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Ecosystem carbon response of an Arctic peatland to simulated permafrost thaw

Cited by 65 publications

References 126 publications

Thaw Transitions and Redox Conditions Drive Methane Oxidation in a Permafrost Peatland

Thaw Transitions and Redox Conditions Drive Methane Oxidation in a Permafrost Peatland

Large stocks of peatland carbon and nitrogen are vulnerable to permafrost thaw

Net greenhouse gas fluxes from three High Arctic plant communities along a moisture gradient

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