1. Brown carbon: An underlying driving force for rapid atmospheric sulfate formation and haze event
- Author
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Tao Wang, Yangyang Liu, Yue Deng, Xiaozhong Fang, Liwu Zhang, Iqra Nabi, Hanyun Cheng, and Aziz Ur Rahim Bacha
- Subjects
chemistry.chemical_classification ,Environmental Engineering ,Haze ,010504 meteorology & atmospheric sciences ,Chemistry ,010501 environmental sciences ,Particulates ,complex mixtures ,01 natural sciences ,Pollution ,Aerosol ,Atmosphere ,chemistry.chemical_compound ,Environmental chemistry ,Atmospheric chemistry ,Environmental Chemistry ,Humic acid ,Hydroxyl radical ,Sulfate ,Waste Management and Disposal ,0105 earth and related environmental sciences - Abstract
The rapid sulfate formation is a crucial factor determining the explosive growth of fine particles and the frequent occurrence of severe haze events in China. Recent field observations also show that brown carbon is one of the most critical components in aerosol particles sampled during haze episodes. To this day, there is limited knowledge that accesses the role of brown carbon in atmospheric chemistry. In fact, these carbonaceous particulate matters, mainly derived from forest fires, biomass burning, and biogenic release, can act as photosensitizers and produce varieties of active intermediates to alter oxidation capacity. Experimental results in this work provide evidence that hydroxyl radical (∙OH) stems from brown carbon proxies fulvic acid /humic acid (FA/HA) upon irradiation, leading to rapid SO2 oxidation on brown carbon particles in the atmosphere. Further correlation analyses for sulfate formation and chromophore properties of 12 model compounds demonstrate that brown carbon particles with higher aromaticity and E2/E3 (the ratio of absorbance at 254 nm to that at 365 nm) would facilitate ∙OH production and SO2 photo-oxidation. Uptake coefficient measurements and sulfate production rate estimation indicate that brown carbon could gain importance in atmospheric SO2 oxidation. A better understanding of SO2 uptake kinetics on brown carbon surfaces favors in defining new regulations to improve air quality and reduce the harmful effects of haze events on resident health and the environment.
- Published
- 2020
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