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Uptake of Water‐soluble Gas‐phase Oxidation Products Drives Organic Particulate Pollution in BeijingGkatzelis, Georgios I.; Papanastasiou, Dimitrios K.; Karydis, Vlassis A.; Hohaus, Thorsten; Liu, Ying; Schmitt, Sebastian H.; Schlag, Patrick; Fuchs, Hendrik; Novelli, Anna; Chen, Qi; Cheng, Xi; Broch, Sebastian; Dong, Huabin; Holland, Frank; Li, Xin; Liu, Yuhan; Ma, Xuefei; Reimer, David; Rohrer, Franz; Shao, Min; Tan, Zhaofeng; Taraborrelli, Domenico; Tillmann, Ralf; Wang, Haichao; Wang, Yu; Wu, Yusheng; Wu, Zhijun; Zeng, Limin; Zheng, Jun; Hu, Min; Lu, Keding; Hofzumahaus, Andreas; Zhang, Yuanhang; Wahner, Andreas; Kiendler‐Scharr, Astrid
Geophysical research letters, 28 April 2021, 2021-04-28, Letnik: 48, Številka: 8Journal Article
Despite the recent decrease in pollution events in Chinese urban areas, the World Health Organization air quality guideline values are still exceeded. Observations from monitoring networks show a stronger decrease of organic aerosol directly emitted to the atmosphere relative to secondary organic aerosol (SOA) generated from oxidation processes. Here, the uptake of water‐soluble gas‐phase oxidation products is reported as a major SOA contribution to particulate pollution in Beijing, triggered by the increase of aerosol liquid water. In pollution episodes, this pathway is enough to explain the increase in SOA mass, with formaldehyde, acetaldehyde, glycolaldehyde, formic acid, and acetic acid alone explaining 15%–25% of the SOA increase. Future mitigation strategies to reduce non‐methane volatile organic compound emissions should be considered to reduce organic particulate pollution in China. Plain Language Summary In the rapidly developing Chinese economy, air pollution from particulate matter (PM) is a major human health risk factor. We show that secondary organic aerosol (SOA) generated from oxidation processes represent 50%–80% of the organic PM in Beijing. We find that non‐equilibrium dissolution of C1−C2 carbonyl compounds to particles is a major pathway of SOA formation during pollution events. These compounds are ubiquitous products in the chemical oxidation of hydrocarbons; thus, the reduction of a single volatile organic compound precursor would not reduce the organic PM, but rather a broad reduction of the organic reactivity is required. Key Points Secondary organic aerosol generated from oxidation processes dominates organic particulate pollution in Beijing Non‐equilibrium dissolution of carbonyl compounds to particles is a major pathway of SOA formation during haze episodes A broad reduction of the gas‐phase organic reactivity is required to reduce secondary organic aerosol formation in haze events
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