Your search keyword '"Pöschl, Ulrich"' showing total 4 results

1. Seasonality and reduced nitric oxide titration dominated ozone increase during COVID-19 lockdown in eastern China.

Author

Wang, Hongli, Huang, Cheng, Tao, Wei, Gao, Yaqin, Wang, Siwen, Jing, Shengao, Wang, Wenjie, Yan, Rusha, Wang, Qian, An, Jingyu, Tian, Junjie, Hu, Qingyao, Lou, Shengrong, Pöschl, Ulrich, Cheng, Yafang, and Su, Hang

Subjects

COVID-19 pandemic, NITRIC oxide, OZONE, AIR pollution control, STAY-at-home orders, TROPOSPHERIC ozone, NITROGEN oxides

Abstract

With improving PM2.5 air quality, the tropospheric ozone (O3) has become the top issue of China's air pollution control. Here, we combine comprehensive observational data analysis with models to unveil the contributions of different processes and precursors to the change of O3 during COVID-19 lockdown in the Yangtze River Delta (YRD), one of the most urbanized megacity regions of eastern China. Despite a 44 to 47% reduction in volatile organic compounds (VOCs) and nitrogen oxides (NOx) emissions, maximum daily 8-h average (MDA8) ozone concentrations increase from 28 ppbv in pre-lockdown to 43 ppbv in lockdown period. We reproduce this transition with the WRF-Chem model, which shows that ~80% of the increase in MDA8 is due to meteorological factors (seasonal variation and radiation), and ~20% is due to emission reduction. We find that daytime photochemistry does not lead to an increase but rather a decrease of daytime O3 production during the lockdown. However, the reduced O3 production is overwhelmed by the weakened nitric oxide (NO) titration resulting in a net increase of O3 concentration. Although the emission reduction increases O3 concentration, it leads to a decrease in the Ox (O3 + NO2) concentration, suggesting reduced atmospheric oxidation capacity on a regional scale. The dominant effect of NO titration demonstrates the importance of prioritizing VOCs reduction, especially from solvent usage and the petrochemical industry with high emission ratios of VOCs/NOx. [ABSTRACT FROM AUTHOR]

Published

2022

2. Natural gas shortages during the "coal-to-gas" transition in China have caused a large redistribution of air pollution in winter 2017.

Author

Siwen Wang, Hang Su, Chuchu Chen, Wei Tao, Streets, David G., Zifeng Lu, Bo Zheng, Carmichael, Gregory R., Lelieveld, Jos, Pöschl, Ulrich, and Yafang Cheng

Subjects

AIR pollution, NATURAL gas, PARTICULATE matter, AIR quality, SCARCITY

Abstract

The Chinese "coal-to-gas" and "coal-to-electricity" strategies aim at reducing dispersed coal consumption and related air pollution by promoting the use of clean and low-carbon fuels in northern China. Here, we show that on top of meteorological influences, the effective emission mitigation measures achieved an average decrease of fine particulate matter (PM2.5) concentrations of ∼14% in Beijing and surrounding areas (the "2+26" pilot cities) in winter 2017 compared to the same period of 2016, where the dispersed coal control measures contributed ∼60% of the total PM2.5 reductions. However, the localized air quality improvement was accompanied by a contemporaneous ∼15% upsurge of PM2.5 concentrations over large areas in southern China. We find that the pollution transfer that resulted from a shift in emissions was of a high likelihood caused by a natural gas shortage in the south due to the coal-to-gas transition in the north. The overall shortage of natural gas greatly jeopardized the air quality benefits of the coal-to-gas strategy in winter 2017 and reflects structural challenges and potential threats in China's clean-energy transition. [ABSTRACT FROM AUTHOR]

Published

2020

3. Natural gas shortages during the "coal-to-gas" transition in China have caused a large redistribution of air pollution in winter 2017.

Author

Wang S, Su H, Chen C, Tao W, Streets DG, Lu Z, Zheng B, Carmichael GR, Lelieveld J, Pöschl U, and Cheng Y

Subjects

China, Cities, Environmental Policy, Heating, Particulate Matter analysis, Air Pollution analysis, Coal analysis, Natural Gas analysis, Seasons

Abstract

The Chinese "coal-to-gas" and "coal-to-electricity" strategies aim at reducing dispersed coal consumption and related air pollution by promoting the use of clean and low-carbon fuels in northern China. Here, we show that on top of meteorological influences, the effective emission mitigation measures achieved an average decrease of fine particulate matter (PM 2.5 ) concentrations of ∼14% in Beijing and surrounding areas (the "2+26" pilot cities) in winter 2017 compared to the same period of 2016, where the dispersed coal control measures contributed ∼60% of the total PM 2.5 reductions. However, the localized air quality improvement was accompanied by a contemporaneous ∼15% upsurge of PM 2.5 concentrations over large areas in southern China. We find that the pollution transfer that resulted from a shift in emissions was of a high likelihood caused by a natural gas shortage in the south due to the coal-to-gas transition in the north. The overall shortage of natural gas greatly jeopardized the air quality benefits of the coal-to-gas strategy in winter 2017 and reflects structural challenges and potential threats in China's clean-energy transition., Competing Interests: The authors declare no competing interest., (Copyright © 2020 the Author(s). Published by PNAS.)

Published

2020

4. Radical Formation by Fine Particulate Matter Associated with Highly Oxygenated Molecules.

Author

Tong H, Zhang Y, Filippi A, Wang T, Li C, Liu F, Leppla D, Kourtchev I, Wang K, Keskinen HM, Levula JT, Arangio AM, Shen F, Ditas F, Martin ST, Artaxo P, Godoi RHM, Yamamoto CI, de Souza RAF, Huang RJ, Berkemeier T, Wang Y, Su H, Cheng Y, Pope FD, Fu P, Yao M, Pöhlker C, Petäjä T, Kulmala M, Andreae MO, Shiraiwa M, Pöschl U, Hoffmann T, and Kalberer M

Subjects

Aerosols, Beijing, China, Finland, Air Pollutants, Particulate Matter

Abstract

Highly oxygenated molecules (HOMs) play an important role in the formation and evolution of secondary organic aerosols (SOA). However, the abundance of HOMs in different environments and their relation to the oxidative potential of fine particulate matter (PM) are largely unknown. Here, we investigated the relative HOM abundance and radical yield of laboratory-generated SOA and fine PM in ambient air ranging from remote forest areas to highly polluted megacities. By electron paramagnetic resonance and mass spectrometric investigations, we found that the relative abundance of HOMs, especially the dimeric and low-volatility types, in ambient fine PM was positively correlated with the formation of radicals in aqueous PM extracts. SOA from photooxidation of isoprene, ozonolysis of α- and β-pinene, and fine PM from tropical (central Amazon) and boreal (Hyytiälä, Finland) forests exhibited a higher HOM abundance and radical yield than SOA from photooxidation of naphthalene and fine PM from urban sites (Beijing, Guangzhou, Mainz, Shanghai, and Xi'an), confirming that HOMs are important constituents of biogenic SOA to generate radicals. Our study provides new insights into the chemical relationship of HOM abundance, composition, and sources with the yield of radicals by laboratory and ambient aerosols, enabling better quantification of the component-specific contribution of source- or site-specific fine PM to its climate and health effects.

Published

2019