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Liquid-liquid phase separation reduces radiative absorption by aged black carbon aerosols

Jian Zhang, Yuanyuan Wang, Xiaomi Teng, Lei Liu, Yisheng Xu, Lihong Ren, Zongbo Shi, Yue Zhang, Jingkun Jiang, Dantong Liu, Min Hu, Longyi Shao, Jianmin Chen, Scot T. Martin, Xiaoye Zhang, Weijun Li

2022Communications Earth & Environment57 citationsDOIOpen Access PDF

Abstract

Abstract Black carbon aerosols absorb radiation and their absorptive strength is influenced by particle mixing structures and coating compositions. Liquid-liquid phase separation can move black carbon to organic particle coatings which affects absorptive capacity, but it is unclear which conditions favour this redistribution. Here we combine field observations, laboratory experiments, and transmission electron microscopy to demonstrate that liquid-liquid phase separation redistributes black carbon from inorganic particle cores to organic coatings under a wide range of relative humidity. We find that the ratio of organic coating thickness to black carbon size influences the redistribution. When the ratio is lower than 0.12, over 90% of black carbon is inside inorganic salt cores. However, when the ratio exceeds 0.24, most black carbon is redistributed to organic coatings, due to a change in its affinity for inorganic and organic phases. Using an optical calculation model, we estimate that black carbon redistribution reduces the absorption enhancement effect by 28–34%. We suggest that climate models assuming a core-shell particle structure probably overestimate radiative absorption of black carbon aerosols by approximately 18%.

Topics & Concepts

Carbon blackAbsorption (acoustics)Carbon fibersParticle sizeRadiative transferMaterials scienceParticle (ecology)Redistribution (election)Total organic carbonAnalytical Chemistry (journal)ChemistryChemical engineeringComposite materialChromatographyOpticsEnvironmental chemistryNatural rubberPoliticsEngineeringGeologyPhysical chemistryLawOceanographyPolitical scienceComposite numberPhysicsAtmospheric chemistry and aerosolsAtmospheric aerosols and cloudsAir Quality and Health Impacts
Liquid-liquid phase separation reduces radiative absorption by aged black carbon aerosols | Litcius