Mechanisms of O3 and PM2.5 evolution along the cold wave passage in Eastern China

Min Shao; Changhui Xu; Shun Lv; Xueren Jin; Qing Mu; Jialei Zhu

doi:10.1038/s41612-025-01088-8

Mechanisms of O3 and PM2.5 evolution along the cold wave passage in Eastern China

Min Shao, Changhui Xu, Shun Lv, Xueren Jin, Qing Mu, Jialei Zhu

Department of Health and Environmental Sciences

Research output: Contribution to journal › Article › peer-review

Abstract

Cold wave (CW) systems in China, driven by strong northerly winds, typically clean the atmosphere but can also transport pollutants. However, elevated PM2.5 and O3 levels often precede CW events, with key processes remaining unclear. This study analyzes over 2000 in-situ observations (2014–2022), atmospheric reanalysis, and WRF-CAMx simulations to examine CW impacts on air pollution over eastern China. A three-day compressional heating period before CW events alters planetary boundary layer (PBL) dynamics, influencing pollutant levels. PM2.5 is driven by wind speed, PBL height (PBLH), and mean sea level pressure (MSLP), while O3 is influenced by temperature, humidity, solar radiation, PBLH, and MSLP. Though CWs generally clean the air on the day of its arrival, ~18% of cases show increased PM2.5 due to enhanced secondary formation and suppressed PBLH. Numerical simulations reveal CW-induced long-range pollutant transport and highlight critical meteorological-pollution interactions before CW events.

Original language	English
Article number	199 (2025)
Journal	npj Climate and Atmospheric Science
Volume	8
Issue number	1
DOIs	https://doi.org/10.1038/s41612-025-01088-8
Publication status	Published - 24 May 2025

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10.1038/s41612-025-01088-8

Cite this

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title = "Mechanisms of O3 and PM2.5 evolution along the cold wave passage in Eastern China",

abstract = "Cold wave (CW) systems in China, driven by strong northerly winds, typically clean the atmosphere but can also transport pollutants. However, elevated PM2.5 and O3 levels often precede CW events, with key processes remaining unclear. This study analyzes over 2000 in-situ observations (2014–2022), atmospheric reanalysis, and WRF-CAMx simulations to examine CW impacts on air pollution over eastern China. A three-day compressional heating period before CW events alters planetary boundary layer (PBL) dynamics, influencing pollutant levels. PM2.5 is driven by wind speed, PBL height (PBLH), and mean sea level pressure (MSLP), while O3 is influenced by temperature, humidity, solar radiation, PBLH, and MSLP. Though CWs generally clean the air on the day of its arrival, ~18% of cases show increased PM2.5 due to enhanced secondary formation and suppressed PBLH. Numerical simulations reveal CW-induced long-range pollutant transport and highlight critical meteorological-pollution interactions before CW events.",

author = "Min Shao and Changhui Xu and Shun Lv and Xueren Jin and Qing Mu and Jialei Zhu",

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T1 - Mechanisms of O3 and PM2.5 evolution along the cold wave passage in Eastern China

AU - Shao, Min

AU - Xu, Changhui

AU - Lv, Shun

AU - Jin, Xueren

AU - Mu, Qing

AU - Zhu, Jialei

PY - 2025/5/24

Y1 - 2025/5/24

N2 - Cold wave (CW) systems in China, driven by strong northerly winds, typically clean the atmosphere but can also transport pollutants. However, elevated PM2.5 and O3 levels often precede CW events, with key processes remaining unclear. This study analyzes over 2000 in-situ observations (2014–2022), atmospheric reanalysis, and WRF-CAMx simulations to examine CW impacts on air pollution over eastern China. A three-day compressional heating period before CW events alters planetary boundary layer (PBL) dynamics, influencing pollutant levels. PM2.5 is driven by wind speed, PBL height (PBLH), and mean sea level pressure (MSLP), while O3 is influenced by temperature, humidity, solar radiation, PBLH, and MSLP. Though CWs generally clean the air on the day of its arrival, ~18% of cases show increased PM2.5 due to enhanced secondary formation and suppressed PBLH. Numerical simulations reveal CW-induced long-range pollutant transport and highlight critical meteorological-pollution interactions before CW events.

AB - Cold wave (CW) systems in China, driven by strong northerly winds, typically clean the atmosphere but can also transport pollutants. However, elevated PM2.5 and O3 levels often precede CW events, with key processes remaining unclear. This study analyzes over 2000 in-situ observations (2014–2022), atmospheric reanalysis, and WRF-CAMx simulations to examine CW impacts on air pollution over eastern China. A three-day compressional heating period before CW events alters planetary boundary layer (PBL) dynamics, influencing pollutant levels. PM2.5 is driven by wind speed, PBL height (PBLH), and mean sea level pressure (MSLP), while O3 is influenced by temperature, humidity, solar radiation, PBLH, and MSLP. Though CWs generally clean the air on the day of its arrival, ~18% of cases show increased PM2.5 due to enhanced secondary formation and suppressed PBLH. Numerical simulations reveal CW-induced long-range pollutant transport and highlight critical meteorological-pollution interactions before CW events.

U2 - 10.1038/s41612-025-01088-8

DO - 10.1038/s41612-025-01088-8

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