Litcius/Paper detail

Unexpected Biomass Burning Aerosol Absorption Enhancement Explained by Black Carbon Mixing State

Cyrielle Denjean, Joël Brito, Quentin Libois, Marc Mallet, Thierry Bourrianne, Frédéric Burnet, Régis Dupuy, Cyrille Flamant, Peter Knippertz

2020Geophysical Research Letters84 citationsDOIOpen Access PDF

Abstract

Abstract Direct and semi‐direct radiative effects of biomass burning aerosols (BBA) from southern and central African fires are still widely debated, in particular because climate models have been unsuccessful in reproducing the low single scattering albedo in BBA over the eastern Atlantic Ocean. Using state‐of‐the‐art airborne in situ measurements and Mie scattering simulations, we demonstrate that low single scattering albedo in well‐aged BBA plumes over southern West Africa results from the presence of strongly absorbing refractory black carbon (rBC), whereas the brown carbon contribution to the BBA absorption is negligible. Coatings enhance light absorption by rBC‐containing particles by up to 210%. Our results show that accounting for the diversity in black carbon mixing state by combining internal and external configurations is needed to accurately estimate the optical properties and henceforth the shortwave direct radiative effect and heating rate of BBA over southern West Africa.

Topics & Concepts

Single-scattering albedoAlbedo (alchemy)AerosolShortwaveCarbon blackAtmospheric sciencesRadiative transferEnvironmental scienceAbsorption (acoustics)ScatteringCarbon fibersMie scatteringMixing (physics)ClimatologyMaterials scienceLight scatteringPhysicsMeteorologyGeologyOpticsNatural rubberComposite materialPerformance artArtArt historyComposite numberQuantum mechanicsAtmospheric chemistry and aerosolsAtmospheric aerosols and cloudsAtmospheric Ozone and Climate