Litcius/Paper detail

Divergent Impacts of Biomass Burning and Fossil Fuel Combustion Aerosols on Fog‐Cloud Microphysics and Chemistry: Novel Insights From Advanced Aerosol‐Fog Sampling

Ye Kuang, Weiqi Xu, Weiqi Xu, Jiangchuan Tao, Biao Luo, Li Liu, Hanbin Xu, Wanyun Xu, Wanyun Xu, Biao Xue, Miaomiao Zhai, Pengfei Liu, Yele Sun

2024Geophysical Research Letters18 citationsDOIOpen Access PDF

Abstract

Abstract Activation of biomass burning aerosols (BBA) and fossil fuel combustion aerosols (FFA) in fogs and clouds significantly impact regional air quality through aqueous chemistry and climate by affecting cloud microphysics. However, we lack direct observations of how these aerosols behave in fogs and clouds. Using a newly developed aerosol‐cloud sampling system, we conducted observations during fog events and found that BBA, despite their high organic content, effectively contributed to super‐micron interstitial aerosols and fog droplets in low supersaturation fogs. In contrast, FFA, predominantly externally mixed organic, did not grow beyond the super‐micron size in fogs due to their near‐hydrophobic nature. Measurements conducted under supersaturations relevant for cloud formation revealed that portions of FFA could serve as cloud condensation nuclei, but only when supersaturation exceeded ∼0.14%. These findings have broad implications for future investigations into the influence of BBA and FFA on fog and cloud chemistry and their interactions with clouds.

Topics & Concepts

Cloud condensation nucleiFogAerosolSupersaturationEnvironmental scienceAtmospheric sciencesCloud physicsLiquid water contentMeteorologyCombustionCloud computingChemistryGeologyPhysicsComputer scienceOperating systemOrganic chemistryAtmospheric chemistry and aerosolsAtmospheric aerosols and cloudsAtmospheric and Environmental Gas Dynamics