Litcius/Paper detail

Climate warming and elevated CO2 alter peatland soil carbon sources and stability

Nicholas O. E. Ofiti, Michael W. Schmidt, Samuel Abiven, Paul J. Hanson, Colleen M. Iversen, Rachel Wilson, Joel E. Kostka, Guido L. B. Wiesenberg, Avni Malhotra

2023Nature Communications73 citationsDOIOpen Access PDF

Abstract

Abstract Peatlands are an important carbon (C) reservoir storing one-third of global soil organic carbon (SOC), but little is known about the fate of these C stocks under climate change. Here, we examine the impact of warming and elevated atmospheric CO 2 concentration (eCO 2 ) on the molecular composition of SOC to infer SOC sources (microbe-, plant- and fire-derived) and stability in a boreal peatland. We show that while warming alone decreased plant- and microbe-derived SOC due to enhanced decomposition, warming combined with eCO 2 increased plant-derived SOC compounds. We further observed increasing root-derived inputs (suberin) and declining leaf/needle-derived inputs (cutin) into SOC under warming and eCO 2 . The decline in SOC compounds with warming and gains from new root-derived C under eCO 2 , suggest that warming and eCO 2 may shift peatland C budget towards pools with faster turnover. Together, our results indicate that climate change may increase inputs and enhance decomposition of SOC potentially destabilising C storage in peatlands.

Topics & Concepts

PeatEnvironmental scienceGlobal warmingSoil carbonBorealCarbon cycleClimate changeGlobal-warming potentialCarbon fibersGreenhouse gasEcosystemAtmospheric sciencesEcologyEnvironmental chemistrySoil scienceChemistrySoil waterGeologyBiologyComposite numberComposite materialMaterials sciencePeatlands and Wetlands EcologyCoastal wetland ecosystem dynamicsFire effects on ecosystems