Your search keyword '"WANG, Yanyang"' showing total 2 results

1. Dramatic changes in atmospheric pollution source contributions for a coastal megacity in northern China from 2011 to 2020.

Author

Liu, Baoshuang, Wang, Yanyang, Meng, He, Dai, Qili, Diao, Liuli, Wu, Jianhui, Shi, Laiyuan, Wang, Jing, Zhang, Yufen, and Feng, Yinchang

Subjects

EMISSIONS (Air pollution), AIR quality management, MEGALOPOLIS, COAL combustion, GREENHOUSE gas mitigation, DUST, OZONE

Abstract

Understanding the effectiveness of long-term air pollution regulatory measures is important for control policy formulation. Efforts have been made using chemical transport modelling and statistical approaches to evaluate the efficacy of the Clean Air Action Plan (CAAP; 2013–2017) and the Blue Sky Protection Campaign (BSPC; 2018–2020) enacted in China. Changes in air quality due to reduction in emissions can be masked by meteorology, making it highly challenging to reveal the real effects of control measures. A knowledge gap still existed with respect to how sources changed before and after the CAAP and BSPC were implemented, respectively, particularly in coastal areas where anthropogenic emissions mixed with additional natural sources (e.g. marine aerosol). This work applied a machine-learning-based meteorological normalization approach to decouple the meteorological effects from air quality trend in a coastal city in northern China (Qingdao). Secondly, the relative changes in source contributions to ambient PM2.5 with a ∼ 10-year observation interval (2011–2012, 2016, and 2019) were also investigated. We discovered that the largest emission reduction section was likely from coal combustion as the meteorologically normalized SO2 dropped by ∼ 15.5 %yr-1 , and the annual average dispersion-normalized SO42- decreased by ∼ 41.5 %. Change in the meteorologically normalized NO2 was relatively stable (∼ 1.0 %yr-1), and NO3- changed inappreciably in 2016–2019 but was significantly higher than that prior to the CAAP. Crustal dust decreased remarkably after the CAAP began. Industrial emissions, for example, steel-related smelting, decreased after 2016 due to the relocation of steel-making enterprises. Note that vehicle emissions were increased in importance as opposed to the other primary sources. Similar to other megacities, Qingdao is also at risk of increased ozone pollution that in turn facilitates secondary-particle formation in the future. The policy assessment approaches applied in this work also work for other places where air quality management is highly in demand to reduce air pollution. [ABSTRACT FROM AUTHOR]

Published

2022

2. Potential health risks of inhaled toxic elements and risk sources during different COVID-19 lockdown stages in Linfen, China.

Author

Wang Y, Liu B, Zhang Y, Dai Q, Song C, Duan L, Guo L, Zhao J, Xue Z, Bi X, and Feng Y

Subjects

Adult, Child, China, Communicable Disease Control, Environmental Monitoring, Humans, Particulate Matter analysis, SARS-CoV-2, Vehicle Emissions analysis, Air Pollutants analysis, COVID-19

Abstract

Levels of toxic elements in ambient PM 2.5 were measured from 29 October 2019 to 30 March 2020 in Linfen, China, to assess the health risks they posed and to identify critical risk sources during different periods of the COVID-19 lockdown and haze episodes using positive matrix factorization (PMF) and a health-risk assessment model. The mean PM 2.5 concentration during the study period was 145 μg/m 3 , and the 10 investigated toxic elements accounted for 0.31% of the PM 2.5 mass. The total non-cancer risk (HI) and total cancer risk (TCR) of the selected toxic elements exceed the US EPA limits for children and adults. The HI for children was 2.3 times that for adults for all periods, which is likely due to the high inhalation rate per unit body weight for children. While the TCR for adults was 1.7 times that of children, which is mainly attributed to potential longer exposure duration for adults. The HI and TCR of the toxic elements during full lockdown were reduced by 66% and 58%, respectively, compared to their pre-lockdown levels. The HI and TCR were primarily attributable to Mn and As, respectively. Health risks during haze episodes were significantly higher than the average levels during COVID-19 lockdowns, though the HI and TCR of the selected toxic elements during full-lockdown haze episodes were 68% and 17% lower, respectively, than were the levels during pre-lockdown haze episodes. During the study period, fugitive dust and steel-related smelting were the highest contributors to HI and TCR, respectively, and decreased in these emission sources contributed the most to the lower health risks observed during the full lockdown. There, the control of these sources is critical to effectively reduce public health risks., (Copyright © 2021 Elsevier Ltd. All rights reserved.)

Published

2021