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A spatial emergent constraint on the sensitivity of soil carbon turnover to global warming

Rebecca Varney, Sarah Chadburn, Pierre Friedlingstein, Eleanor Burke, Charles D. Koven, Gustaf Hugelius, Peter M. Cox

2020Nature Communications131 citationsDOIOpen Access PDF

Abstract

Abstract Carbon cycle feedbacks represent large uncertainties in climate change projections, and the response of soil carbon to climate change contributes the greatest uncertainty to this. Future changes in soil carbon depend on changes in litter and root inputs from plants and especially on reductions in the turnover time of soil carbon ( τ s ) with warming. An approximation to the latter term for the top one metre of soil (Δ C s,τ ) can be diagnosed from projections made with the CMIP6 and CMIP5 Earth System Models (ESMs), and is found to span a large range even at 2 °C of global warming (−196 ± 117 PgC). Here, we present a constraint on Δ C s,τ , which makes use of current heterotrophic respiration and the spatial variability of τ s inferred from observations. This spatial emergent constraint allows us to halve the uncertainty in Δ C s,τ at 2 °C to −232 ± 52 PgC.

Topics & Concepts

Carbon cycleEnvironmental scienceGlobal warmingAtmospheric sciencesSoil carbonCarbon fibersSoil respirationLitterGlobal changeConstraint (computer-aided design)Climate changeRange (aeronautics)ClimatologySoil scienceEcologyEcosystemSoil waterMathematicsBiologyGeologyComposite numberMaterials scienceComposite materialAlgorithmGeometryClimate variability and modelsPlant Water Relations and Carbon DynamicsAtmospheric and Environmental Gas Dynamics
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