Wintertime ozone surges: The critical role of alkene ozonolysis
Jin Yang, Yangzong Zeren, Hai Guo, Yu Wang, Xiaopu Lyu, Beining Zhou, Hong Gao, Dawen Yao, Zhanxiang Wang, Shizhen Zhao, Jun Li, Gan Zhang
Abstract
Ozone (O 3 ) pollution is usually linked to warm weather and strong solar radiation, making it uncommon in cold winters. However, an unusual occurrence of four high O 3 episode days (with maximum hourly concentrations exceeding 100 ppbv and peaking at 121 ppbv) was recorded in January 2018 in Lanzhou city, China. During these episodes, the average daytime concentration of total non-methane volatile organic compounds (TVOCs) reached 153.4 ± 19.0 ppbv, with alkenes—largely emitted from the local petrochemical industry—comprising 82.3 ± 13.1 ppbv. Here we show a photochemical box model coupled with a Master Chemical Mechanism to elucidate the mechanisms behind this unusual wintertime O 3 pollution. We find that the typically low temperatures (−1.7 ± 1.3 °C) and weak solar radiation (263.6 ± 60.7 W m - 2 ) of those winter episode days had a minimal effect on the reactivity of VOCs with OH radicals. Instead, the ozonolysis of alkenes generated Criegee intermediates, which rapidly decomposed into substantial RO x radicals (OH, HO 2 , and RO 2 ) without sunlight. This radical production led to the oxidation of VOCs, with alkene ozonolysis ultimately contributing to 89.6 ± 8.7% of the O 3 formation during these episodes. This mechanism did not activate at night due to the depletion of O 3 by the NO titration effect. Furthermore, the findings indicate that a reduction of alkenes by 28.6% or NO x by 27.7% in the early afternoon could significantly mitigate wintertime O 3 pollution. Overall, this study unravels the unique mechanism of alkene-induced winter O 3 pollution and offers a reference for winter O 3 reduction strategies in the petrochemical industrial regions. • Extremely high O 3 concentrations peaking at 121 ppbv were unexpectedly observed in 2018 winter in Lanzhou, China. • The wintertime O 3 surges were driven by the abundant emissions of alkenes with ambient levels reaching 82.3 ± 13.1 ppbv. • Alkene ozonolysis played a critical role in generating 85.8 ± 11.0% of OH, HO 2 , and RO 2 radicals. • Alkene ozonolysis led to the further oxidation of VOCs and substantial 89.6 ± 8.7 % of O 3 formation.