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Chemistry-driven changes strongly influence climate forcing from vegetation emissions

James Weber, Scott Archer‐Nicholls, Nathan Luke Abraham, Youngsub Matthew Shin, Paul T. Griffiths, Daniel P. Grosvenor, Catherine E. Scott, Alexander T. Archibald

2022Nature Communications42 citationsDOIOpen Access PDF

Abstract

Abstract Biogenic volatile organic compounds (BVOCs) affect climate via changes to aerosols, aerosol-cloud interactions (ACI), ozone and methane. BVOCs exhibit dependence on climate (causing a feedback) and land use but there remains uncertainty in their net climatic impact. One factor is the description of BVOC chemistry. Here, using the earth-system model UKESM1, we quantify chemistry’s influence by comparing the response to doubling BVOC emissions in the pre-industrial with standard and state-of-science chemistry. The net forcing (feedback) is positive: ozone and methane increases and ACI changes outweigh enhanced aerosol scattering. Contrary to prior studies, the ACI response is driven by cloud droplet number concentration (CDNC) reductions from suppression of gas-phase SO 2 oxidation. With state-of-science chemistry the feedback is 43% smaller as lower oxidant depletion yields smaller methane increases and CDNC decreases. This illustrates chemistry’s significant influence on BVOC’s climatic impact and the more complex pathways by which BVOCs influence climate than currently recognised.

Topics & Concepts

MethaneRadiative forcingAtmospheric sciencesAerosolForcing (mathematics)OzoneAtmospheric chemistryEnvironmental scienceClimate systemChemistryClimate changeClimate modelClimatologyEnvironmental chemistryMeteorologyEcologyPhysicsOrganic chemistryBiologyGeologyAtmospheric chemistry and aerosolsAtmospheric and Environmental Gas DynamicsAtmospheric Ozone and Climate
Chemistry-driven changes strongly influence climate forcing from vegetation emissions | Litcius