Characterization of organic aerosols and their precursors in southern China during a severe haze episode in January 2017

The rapid industrialization and economic development in the Pearl River Delta (PRD) region of southern China have led to a substantial increase in anthropogenic emissions and hence frequent haze pollution over the past two decades. In early January 2017, a severe regional haze pollution episode was...

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Bibliographic Details
Published in:The Science of the total environment 2019-11, Vol.691, p.101-111
Main Authors: Chang, Di, Wang, Zhe, Guo, Jia, Li, Tao, Liang, Yiheng, Kang, Lingyan, Xia, Men, Wang, Yaru, Yu, Chuan, Yun, Hui, Yue, Dingli, Wang, Tao
Format: Article
Language:English
Subjects:
Haze pollution
Organic acids
Oxygenated volatile organic compounds
Photochemistry
WSOC
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Summary:The rapid industrialization and economic development in the Pearl River Delta (PRD) region of southern China have led to a substantial increase in anthropogenic emissions and hence frequent haze pollution over the past two decades. In early January 2017, a severe regional haze pollution episode was captured in the PRD region, with a peak PM2.5 concentration of around 400μgm−3, the highest value ever reported at this site. During the haze episode, elevated concentrations of oxygenated volatile organic compounds (OVOCs, 33±16 ppbv) and organic matter (41±15μg m−3) were observed, indicating the enhanced roles of secondary organic aerosols (SOAs) in the formation of haze pollution. Water-soluble organic carbon (WSOC, 12.8±5.5μg C m−3) dominated the organic aerosols, with a WSOC/OC ratio of 0.63±0.12 and high correlation (R=0.85) with estimated secondary organic carbon (SOC), suggesting the predominance of a secondary origin of the measured organic aerosols during the haze episode. Four carboxylic acids (oxalic, acetic, formic, and pyruvic acids) were characterized in the aerosols (1.30±0.38μgm−3) and accounted for 3.6±1.2% of WSOC in carbon mass, with oxalic acid as the most abundant species. The simultaneous measurements of volatile organic compounds (VOCs), OVOCs, and organic acids in aerosols at this site provided an opportunity to investigate the relationship between the precursors and the products, as well as the potential formation pathways. Water-soluble aldehydes and ketones, predominantly produced via the oxidation of anthropogenic VOCs (mainly propane, toluene, n-butane, and m, p-xylene), were the main contributors of the organic acids. The formation of OVOCs is largely attributed to gas-phase photochemical oxidation, whereas the WSOC and dicarboxylic acids were produced from both photochemistry and nocturnal heterogeneous reactions. These findings provided further insights into the oxidation and evolution of organic compounds during the haze pollution episode. [Display omitted] •Simultaneous measurement of VOCs, OVOCs, and organic aerosol during a haze episode•Enhanced contribution of oxygenated organic matter in haze pollution•Secondary formation of OVOCs from industrial solvent and traffic-emitted VOCs•Photochemical and nocturnal heterogeneous processes are of comparable significance.•Aldehydes and ketones from VOCs oxidation are the main precursors of organic acids.
ISSN:0048-9697
1879-1026
DOI:10.1016/j.scitotenv.2019.07.123