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Stable Sulfur Isotopes Revealed a Major Role of Transition-Metal Ion-Catalyzed SO<sub>2</sub>Oxidation in Haze Episodes

Jianghanyang Li, Yanlin Zhang, Fang Cao, Wenqi Zhang, Mei‐Yi Fan, Xuhui Lee, Greg Michalski

2020Environmental Science & Technology145 citationsDOI

Abstract

Secondary sulfate aerosols played an important role in aerosol formation and aging processes, especially during haze episodes in China. Secondary sulfate was formed via atmospheric oxidation of SO 2 by OH, O 3, H 2 O 2, and transition-metal-catalyzed (TMI) O 2 . However, the relative importance of these oxidants in haze episodes was strongly debated. Here, we use stable sulfur isotopes (δ 34 S) of sulfate aerosols and a Rayleigh distillation model to quantify the contributions of each oxidant during a haze episode in Nanjing, a megacity in China. The observed δ 34 S values of sulfate aerosols showed a negative correlation with sulfur oxidation ratios, which was attributed to the sulfur isotopic fractionations during the sulfate formation processes. Using the average fractionation factor calculated from our observations and zero-dimensional (0-D) atmospheric chemistry modeling estimations, we suggest that OH oxidation was trivial during the haze episode, while the TMI pathway contributed 49 ± 10% of the total sulfate production and O 3 /H 2 O 2 oxidations accounted for the rest. Our results displayed good agreement with several atmospheric chemistry models that carry aqueous and heterogeneous TMI oxidation pathways, suggesting the role of the TMI pathway was significant during haze episodes.

Topics & Concepts

HazeSulfateChemistrySulfurδ34SAerosolEnvironmental chemistryIsotope fractionationAtmospheric chemistryFractionationInorganic chemistryOzoneChemical engineeringOrganic chemistryHydrothermal circulationEngineeringFluid inclusionsAtmospheric chemistry and aerosolsAir Quality and Health ImpactsAtmospheric aerosols and clouds