谷歌學術〽️👰🏿‍♂️：https://scholar.google.com/citations?user=PDR0xMYAAAAJ&hl=zh-CN

教育背景

學士學位（2009年），環境科學，南開大學

碩士學位（2010年）🎴，環境工程🌩，南加州大學

博士學位（2018年）👍🏻👮‍♀️，環境工程🐂，德州農工大學

研究經歷

2011年1月-2012年6月🦖，訪問學者🙆🏿‍♀️，洛杉磯區域水質管理委員會

2012年8月-2017年8月，教學助理/研究助理，德州農工大學

2017年9月-2018年8月，講師，德州農工大學

2018年9月-2021年6月🤸🏻‍♀️，博士後，香港理工大學

2021年8月-現在，副研究員，沐鸣2平台

承擔課題

2018年9月-2021年3月🚣🏻，香港研究局（RGC）資助項目，高度城市化亞熱帶地區的光化學汙染研究

2017年3月-2021年3月，RGC-ANR，海氣交換對沿海特大城市空氣質量的影響

教學經歷

2021年9月 — 今✍️，高級大氣化學👨‍🦽，研究生🧑，沐鸣2娱乐

2022年2月 — 今🤵🏼‍♂️，大氣科學模擬和預測研究進展，研究生😁，沐鸣2娱乐

2022年2月 —今，大氣化學基礎，本科生，沐鸣2娱乐

學術兼職

國際期刊審稿人Geophysical Research Letters, Science of The Total Environment, Environmental Pollution, Chemosphere, npj Climate and Atmospheric Science, Transportation Research Part D, Journal of Environmental Science, and Frontiers of Environmental Science & Engineering journals.

發表論文

（本人名稱加粗，通訊作者加*號）

1. Gao A, Wang J, Poetzscher J, Wang, P.*, et al. Coordinated health effects attributable to particulate matter and other pollutants exposures in the North China Plain[J]. Environmental Research, 2022: 112671.

2. Meng X, Wang W, Shi S, Wang, P.,et al. Evaluating the spatiotemporal ozone characteristics with high-resolution predictions in mainland China, 2013–2019[J]. Environmental Pollution, 2022: 118865.

3. Wang P, Wang P, Chen K, et al. Ground-level ozone simulation using ensemble WRF/Chem predictions over the Southeast United States[J]. Chemosphere, 2022, 287: 132428.

4. Wang P., Zhu, S., Zhang M., et al. (2021). 大氣氧化性及其對二次汙染物形成的貢獻. Chinese Science Bulletin. 10.1360/TB-2021-0761.

5. Wang, P.*, Liu, Y., Dai, J., Fu, X., Wang, X., Guenther, A., and Wang, T*.: Isoprene Emissions Response to Drought and the Impacts on Ozone and SOA in China, Journal of Geophysical Research: Atmosphere,126, e2020JD033263.

6. Wang, P., Shen, J., Zhu, S., Gao, M., Ma, J., Liu, J., Gao, J., and Zhang, H*. (2021):Regional transport: a prominent contributor to short-term PM2.5-related health risk during haze days in the Yangtze River Delta, Environmental Pollution, 275, 116672.

7. Wang, P., Shen, J., Xia, M., Sun, S., Zhang, Y*., Zhang, H., and Wang, X. (2021):Unexpected enhancement of ozone exposure and health risks during National Day in China,Atmos. Chem. Phys.,21, 10347–10356.

8. Zhang, M., Katiyar, A., Zhu, S., Shen, J., Xia, M., Ma, J., Kota, S. H., Wang, P.*, and Zhang, H.*(2021): Impact of reduced anthropogenic emissions during COVID-19 on air quality in India, Atmos. Chem. Phys., 21, 4025–4037.

9. Zhu, S., Poetzscher, J., Shen, J., Wang, S., Wang, P.*, and Zhang, H*. (2021):Comprehensive Insights Into O3 Changes During the COVID-19 From O₃ Formation Regime and Atmospheric Oxidation Capacity, Geophysical Research Letters,48, e2021GL093668.

10. Wang, Y., Zhu, S., Ma, J., Wang, P., Wang, P.*, and Zhang, H*. (2021): Enhanced atmospheric oxidation capacity and associated ozone increases during COVID-19 lockdown in the Yangtze River Delta, Science of The Total Environment, 768, 144796.

11. Wang, S., Zhang, Y., Ma, J., Zhu, S., Shen, J., Wang, P.*, and Zhang, H*. (2021).: Responses of decline in air pollution and recovery associated with COVID-19 lockdown in the Pearl River Delta, Science of The Total Environment, 756, 13868.

12. Shen, J., Zhao, Q., Cheng, Z.*, Wang, P.*, Ying, Q., Liu, J., & Fu, Q. (2020). Insights into source origins and formation mechanisms of nitrate during winter haze episodes in the Yangtze River Delta. Science of The Total Environment, 140187.

13. Wang, P., Wang, T., & Ying, Q. (2020). Regional source apportionment of summertime ozone and its precursors in the megacities of Beijing and Shanghai using a source-oriented chemical transport model. Atmospheric Environment, 224, 117337.

14. Sun, S., Jin, J., Xia, M., Liu, Y., Gao, M., Zou, C.,Wang, T., Lin, Y., Wu, L., Mao, H.*, & Wang, P.* (2020). Vehicle emissions in a middle-sized city of China: Current status and future trends. Environment international, 137, 105514.

15. Liu, L., Shen J., Zhen Cheng. Z.*, Wang, P.*, Ying, Q., Zhao, Q., Zhang Y., Zhao, Y., Fu, Q. (2020). Source apportionment and regional transport of anthropogenic secondary organic aerosol during winter pollution periods in the Yangtze River Delta, China. Science of the Total Environment, 710, 25.

16. Wang, P., Chen, Y., Hu, J., Zhang, H., & Ying, Q. (2019). Source apportionment of summertime ozone in China using a source-oriented chemical transport model. Atmospheric Environment, 211, 79-90.

17. Sun, S., Zhao, G., Wang, T., Jin, J., Wang, P.*, Lin, Y., Ying, Q., Mao, H. (2019). Past and future trends of vehicle emissions in Tianjin, China, from 2000 to 2030. Atmospheric Environment, 209, 182-191.

18. Li, Y., Lin, Y., Zhao, J., Liu, B., Wang, T., Wang, P.*, & Mao, H.* (2019). Control of NOx emissions by air staging in small-and medium-scale biomass pellet boilers. Environmental Science and Pollution Research, 1-13.

19. Wang, P., Chen, Y., Hu, J., Zhang, H., & Ying, Q. (2019). Attribution of Tropospheric Ozone to NOx and VOC Emissions: Considering Ozone Formation in the Transition Regime. Environmental science & technology,53(3), 1404-1412.

20. Wang, P., Ying, Q., Zhang, H., Hu, J., Lin, Y., & Mao, H. (2018). Source apportionment of secondary organic aerosol in China using a regional source-oriented chemical transport model and two emission inventories. Environmental Pollution, 237, 756-766.

21. Wang, P., Schade, G., Estes, M., & Ying, Q. (2017). Improved MEGAN Predictions of Biogenic Isoprene in the Contiguous United States. Atmospheric environment, 148, 337-351.

22. Wang, P., Chen, K., Zhu, S., Wang, P., & Zhang, H. (2020). Severe air pollution events not avoided by reduced anthropogenic activities during COVID-19 outbreak. Resources Conservation and Recycling, 158, 104814.

23. Fu, X., Wang, T., Gao, J., Wang, P., Liu, Y., Wang, S., Zhao, B., & Xue, L. (2020). Persistent Heavy Winter Nitrate Pollution Driven by Increased Photochemical Oxidants in Northern China. Environmental Science & Technology, 54(7), 3881-3889.

24. Dai, J., Liu, Y., Wang, P., Fu, X., Xia, M., & Wang, T. (2020). The impact of sea-salt chloride on ozone through heterogeneous reaction with N2O5 in a coastal region of south China. Atmospheric Environment, 117604.

25. Wu, L., Ren, H., Wang, P., Chen, J., Fang, Y., Hu, W., Ren, L., Deng, J., Song, Y., Li, J., Sun, Y., Wang, Z., Liu, C., Ying, Q., Fu, P. (2019). Aerosol Ammonium in the Urban Boundary Layer in Beijing: An Insight from Nitrogen Isotope Ratios. Environmental Science & Technology Letters, 2019, 6, 7, 389-395.

26. Qiao, X., Wang, P., Zhang, J., Zhang, H., Tang, Y., Hu, J., & Ying, Q. (2019). Spatial-temporal variations and source contributions to forest ozone exposure in China. Science of The Total Environment, 674, 189-199.

27. Hu, J., Wang, P., Ying, Q., Zhang, H., Chen, J., Ge, X., ... & Zhao, Y. (2017). Modeling biogenic and anthropogenic secondary organic aerosol in China. Atmospheric Chemistry and Physics, 17(1), 77-92.

28. Zhang, J., Wang, P., Li, J., Mendola, P., Sherman, S., & Ying, Q. (2016). Estimating population exposure to ambient polycyclic aromatic hydrocarbon in the United States–Part II: Source apportionment and cancer risk assessment. Environment international, 97, 163-170.

29. Zhang, J., Li, J., Wang, P., Chen, G., Mendola, P., Sherman, S., & Ying, Q. (2017). Estimating population exposure to ambient polycyclic aromatic hydrocarbon in the United States–Part I: Model development and evaluation. Environment international, 99, 263-274.

30. Shi, Z., Li, J., Huang, L., Wang, P., Wu, L., Ying, Q., ... & Hu, J. (2017). Source apportionment of fine particulate matter in China in 2013 using a source-oriented chemical transport model. Science of the Total Environment, 601, 1476-1487.

31. Song, C., Ma, C., Zhang, Y., Wang, T., Wu, L., Wang, P., ... & Zou, C. (2018). Heavy-duty diesel vehicles dominate vehicle emissions in a tunnel study in northern China. Science of the Total Environment, 637, 431-442.

#以上信息由本人提供，更新時間：2022/03/03