Abstract
Abstract. Permafrost currently stores more than a fourth of global soil carbon. A warming climate makes this carbon increasingly vulnerable to decomposition and release into the atmosphere in the form of greenhouse gases. The resulting climate feedback can be estimated using land surface models, but the high complexity and computational cost of these models make it challenging to use them for estimating uncertainty, exploring novel scenarios, and coupling with other models. We have added a representation of permafrost to the simple, open-source global carbon–climate model Hector, calibrated to be consistent with both historical data and 21st century Earth system model projections of permafrost thaw. We include permafrost as a separate land carbon pool that becomes available for decomposition into both methane (CH4) and carbon dioxide (CO2) once thawed; the thaw rate is controlled by region-specific air temperature increases from a preindustrial baseline. We found that by 2100 thawed permafrost carbon emissions increased Hector’s atmospheric CO2 concentration by 5 %–7 % and the atmospheric CH4 concentration by 7 %–12 %, depending on the future scenario, resulting in 0.2–0.25 ∘C of additional warming over the 21st century. The fraction of thawed permafrost carbon available for decomposition was the most significant parameter controlling the end-of-century temperature change in the model, explaining around 70 % of the temperature variance, and was distantly followed by the initial stock of permafrost carbon, which contributed to about 10 % of the temperature variance. The addition of permafrost in Hector provides a basis for the exploration of a suite of science questions, as Hector can be cheaply run over a wide range of parameter values to explore uncertainty and can be easily coupled with integrated assessment and other human system models to explore the economic consequences of warming from this feedback.
Highlights
Permafrost – soil that continuously remains below 0 ◦C for at least 2 consecutive years – underlies an area of 22 (± 3) ×106 km2, roughly 17 % of the Earth’s exposed land surface (Gruber, 2012), and is estimated to contain 1460– 1600 Pg of organic carbon (Schuur et al, 2018)
The thawed permafrost carbon pool increased to a peak between the middle and the end of the 21st century, after which losses to CH4 and CO2 from heterotrophic respiration began to outpace the carbon inputs from new permafrost thaw
Abrupt thaw is missing from current Earth system models, so our tuning to these models would not account for this mechanism, and it may mean that Hector is somewhat underestimating the permafrost carbon feedback
Summary
Permafrost – soil that continuously remains below 0 ◦C for at least 2 consecutive years – underlies an area of 22 (± 3) ×106 km, roughly 17 % of the Earth’s exposed land surface (Gruber, 2012), and is estimated to contain 1460– 1600 Pg of organic carbon (Schuur et al, 2018). Its carbon becomes available to microbes for decomposition, resulting in the production of carbon dioxide (CO2) and methane (CH4) (Treat et al, 2014; Schädel et al, 2014; Schädel et al, 2016; Bond-Lamberty et al, 2016; Nzotungicimpaye and Zickfeld, 2017) that could lead to further warming (Koven et al, 2011; Schuur et al, 2015) Accounting for this permafrost carbon–climate feedback generally increases projections of greenhouse gas concentrations and global temperatures (Schuur et al, 2015; Burke et al, 2020) and increases estimates of the economic impact of climate change The potential impact ranges from negligible to large, with stronger effects possible, over longer time horizons (Schuur et al, 2015)
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