2010.09-2015.07    bevictor伟德官网 bevictor伟德官网 環境工程專業 博士

2006.09-2010.07    bevictor伟德官网 bevictor伟德官网 環境工程專業 學士

2023年12月至今                 bevictor伟德官网 bevictor伟德官网 副研究員

2018年3月-2023年12月    bevictor伟德官网 bevictor伟德官网 助理研究員

2015年7月-2018年2月    bevictor伟德官网 bevictor伟德官网 土木工程 博士後

汞污染來源與控制

大氣污染物和溫室氣體協同控制

大氣組分的跨介質污染調控

在研項目

1. 大氣汞污染，國家自然科學基金優秀青年科學基金項目，主持

2. 全相态汞、氯、活性氮排放源測量規範及排放特征，國家重點研發計劃課題，主持

3. 城市減污降碳協同增效綜合科學決策支持平台與示範應用，bevictor伟德官网-豐田聯合研究院未來城市跨學科研究與示範專項課題，技術負責

1. 2023年，邱定蕃有色冶金青年科技提名獎

2. 2022年，中國環境科學學會青年科學家獎

3. 2022年，教育部科學技術獎一等獎（公示）

4. 2021年，2020生态環境十大科技進展

2023

1. Han, D.; Wu, Q.; Wen, M.; Tang, Y.; Li, G.; Ren, Y.; Cui, Y.; Li, Z.; Shi, J.; Zhang, Q.; Yin, X.; Wang, S., Isotopic Fractionation Characteristics of Speciated Mercury from Local Biomass Combustion in the Tibetan Plateau. Environ. Sci. Technol. 2023, 57, (12), 4775-4783.

2. Wu, Q.; Han, L.; Li, S.; Wang, S.; Cong, Y.; Liu, K.; Lei, Y.; Zheng, H.; Li, G.; Cai, B.; Hao, J., Facility-Level Emissions and Synergistic Control of Energy-Related Air Pollutants and Carbon Dioxide in China.Environ. Sci. Technol. 2023, 57, (11), 4504-4512.

3. Lv, D. W.; Wu, Q. R.; Ouyang, D. W.; Wen, M. N.; Zhang, G. H.; Wang, S. X.; Duan, L., Differentiated emission control strategy based on comprehensive evaluation of multi-media pollution: Case of mercury emission control. J. Environ. Sci. 2023, 123, 222-234.

2022

1. Tang, Y.; Wang, S.; Li, G.; Han, D.; Liu, K.; Li, Z.; Wu, Q., Elevated Gaseous Oxidized Mercury Revealed by a Newly Developed Speciated Atmospheric Mercury Monitoring System. Environ. Sci. Technol. 2022, 56, (12), 7707–7715.

2. Li, G.; Wang, S.; Wu, Q.; Li, J.; Chen, Z.; Li, J.; Wang, F.; Han, D.; Li, Z.; Tang, Y.; Ouyang, D.; Liu, K., Mercury emission characteristics and mechanism in the raw mill system of cement clinker production. J. Hazard. Mater. 2022, 430, 128403.

3. Cui, Y.; Wu, Q.; Liu, K.; Wang, S.; Wang, X.; Jiang, T.; Meng, B.; Wu, Y.; Guo, J., Source Apportionment of Speciated Mercury in Chinese Rice Grain Using a High-Resolution Model. ACS Environmental Au 2022, 2, (4), 324-335.

4. Zhang, J. W.; Sun, X. H.; Deng, J. G.; Li, G. L.; Li, Z. J.; Jiang, J. K.; Wu, Q. R.; Duan, L., Emission characteristics of heavy metals from a typical copper smelting plant. J. Hazard. Mater. 2022, 424, (424), 127311.

5. Ouyang, D. W.; Wu, Q. R.; Li, G. L.; Han, D. M.; Wang, S. X., Impacts of Material Input and Production Process on the Isotopic Fingerprint of Atmospheric Mercury Emissions from Cement Clinker Production. Environ Sci Tech Let 2022, 9, 900-905.

6. Han, D. M.; Wang, S. X.; Wu, Q. R.; Tang, Y.; Wen, M. N., Measuring and Regression Modeling of Gas-Particle Partitioning of Atmospheric Oxidized Mercury at a Coastal Site in Shanghai. Atmosphere 2022, 13, (12), 2014.

7. Wu, Q. R.; Zhang, Y. X.; Li, P.; Fu, X. W.; Zhang, Q. G.; Wang, X.; Chen, L.; Wang, S. X.; Wang, F. Y.; Feng, X. B., Ecosystem Mercury Recovery and Health Benefit Under the Minamata Convention in a Changing Climate. Reviews of Environmental Contamination and Toxicology 2022, 260, (1), 15.

8. Liu, K.; Wu, Q.; Ren, Y.; Wang, S., Air Pollutant Emissions from Residential Solid Fuel Combustion in the Pan-Third Pole Region. Environ. Sci. Technol. 2022, 56, (22), 15347-15355.

9. Liu, K. Y.; Wu, Q. R.; Wang, S. X.; Chang, X.; Tang, Y.; Wang, L.; Liu, T. H.; Zhang, L.; Zhao, Y.; Wang, Q. G.; Chen, J. S., Improved atmospheric mercury simulation using updated gas-particle partition and organic aerosol concentrations. J. Environ. Sci. 2022, 119, 106-118.

10. Cao, S.; Zhang, L.; Zhang, Y.; Wang, S.; Wu, Q., Impacts of Removal Compensation Effect on the Mercury Emission Inventories for Nonferrous Metal (Zinc, Lead, and Copper) Smelting in China. Environ. Sci. Technol. 2022, 56, (4), 2163-2171.