Triplet-Excited Dissolved Organic Matter Efficiently Promoted Atmospheric Sulfate Production: Kinetics and Mechanisms

Brown carbons (BrCs) play a pivotal role in the light absorption by aerosol particulates by exerting a positive radiative forcing effect that contributes to global warming. Beyond impacts on radiative balance, some BrCs, as photosensitizers, can generate reactive triplet-state molecules toward various atmospheric molecules upon photoexcitation. The significance of photosensitization has been increasingly recognized, particularly in the context of escalated global wildfire incidents that emit substantial BrCs. We focus on the complex atmospheric photosensitization by discussing the current challenges, including (1) the diverse reactivities of the photosensitizer mixture in atmospheric particles, (2) the methodologies for investigating photosensitization processes, (3) the driving factors of photosensitization, and (4) the typical pathways and mechanisms of atmospheric photosensitized reactions. Lastly, we advise future research to focus on the refined parametrization of triplet and singlet oxygen concentrations, alongside their complex reactivities.

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Biomass-burning organic aerosols as a pool of atmospheric reactive triplets to drive multiphase sulfate formation

Liang,

Zhou,

Chang

et al. 2024

Proc. Natl. Acad. Sci. U.S.A.

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Biomass-burning organic aerosol(s) (BBOA) are rich in brown carbon, which significantly absorbs solar irradiation and potentially accelerates global warming. Despite its importance, the multiphase photochemistry of BBOA after light absorption remains poorly understood due to challenges in determining the oxidant concentrations and the reaction kinetics within aerosol particles. In this study, we explored the photochemical reactivity of BBOA particles in multiphase S(IV) oxidation to sulfate. We found that sulfate formation in BBOA particles under light is predominantly driven by photosensitization involving the triplet excited states ( 3 BBOA * ) instead of iron, nitrate, and S(IV) photochemistry. Rates in BBOA particles are three orders of magnitude higher than those observed in the bulk solution, primarily due to the fast interfacial reactions. Our results highlight that the chemistry of 3 BBOA * in particles can greatly contribute to the formation of sulfate, as an example of the secondary pollutants. Photosensitization of BBOA will likely become increasingly crucial due to the intensified global wildfires.

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Triplet-Excited Dissolved Organic Matter Efficiently Promoted Atmospheric Sulfate Production: Kinetics and Mechanisms

Cited by 3 publications

References 48 publications

Effect of cloud chemistry on seasonal variations of sulfate and its precursors in China

Effect of cloud chemistry on seasonal variations of sulfate and its precursors in China

Complexities of Photosensitization in Atmospheric Particles

Biomass-burning organic aerosols as a pool of atmospheric reactive triplets to drive multiphase sulfate formation

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