Litcius/Paper detail

Divergent changes in particulate and mineral-associated organic carbon upon permafrost thaw

Futing Liu, Shuqi Qin, Kai Fang, Leiyi Chen, Yunfeng Peng, Pete Smith, Yuanhe Yang

2022Nature Communications169 citationsDOIOpen Access PDF

Abstract

Permafrost thaw can stimulate microbial decomposition and induce soil carbon (C) loss, potentially triggering a positive C-climate feedback. However, earlier observations have concentrated on bulk soil C dynamics upon permafrost thaw, with limited evidence involving soil C fractions. Here, we explore how the functionally distinct fractions, including particulate and mineral-associated organic C (POC and MAOC) as well as iron-bound organic C (OC-Fe), respond to permafrost thaw using systematic measurements derived from one permafrost thaw sequence and five additional thermokarst-impacted sites on the Tibetan Plateau. We find that topsoil POC content substantially decreases, while MAOC content remains stable and OC-Fe accumulates due to the enriched Fe oxides after permafrost thaw. Moreover, the proportion of MAOC and OC-Fe increases along the thaw sequence and at most of the thermokarst-impacted sites. The relatively enriched stable soil C fractions would alleviate microbial decomposition and weaken its feedback to climate warming over long-term thermokarst development.

Topics & Concepts

PermafrostThermokarstSoil carbonTopsoilEnvironmental chemistryParticulatesTotal organic carbonDecompositionSoil scienceEnvironmental scienceCarbon fibersSoil organic matterPlateau (mathematics)Organic matterSoil waterEarth scienceGeologyChemistryMaterials scienceMathematicsComposite numberOceanographyMathematical analysisOrganic chemistryComposite materialClimate change and permafrostCryospheric studies and observationsGeology and Paleoclimatology Research