职称：研究员/博导

Email：zhanglw@fudan.edu.cn

课题组主页：http://www.zhanglwlab.com

研究方向：气液界面，微液滴，光化学，微塑料，拉曼光谱

（1）个人简历

教育简历

2004-2009, 清华大学，化学系直博，博士

2000-2004, 北京化工大学，应用化学系，学士

工作简历

2014.11-至今，复旦大学，环境科学与工程系，研究员（正高）

2012-2014，英国剑桥大学，物理系，玛丽居里学者博士后

2009-2012，德国汉诺威大学，洪堡学者博士后

博士生导师/方向

大气化学，环境化学

硕士生导师/方向

大气化学，环境化学

学术兼职

•Environmental Science: Advances  副主编

•Proceedings of Royal Society A 编委

•Environmental Science & Ecotechnology 编委

•全球大气化学研究计划（IGAC）中国工作组成员

•中国土壤学会微塑料专委会工作组成员

•中国分析测试协会环境分析分会委员

•中国光学会光谱专业委员会委员

荣誉与奖励

•2022年，英国皇家学会国际合作奖

•2019年，第一届中国化学会青年环境化学奖

•2017年，教育部自然科学奖，一等奖

•2011年，中国百篇最具影响国家学术论文奖

（2）人才培养

本科生课程：

《环境纳米技术（全英文课程）》《大气环境监测：理论与实践》《环境设备基础》《环境科学前沿》

研究生课程：

《纳米技术及其环境效应》

（3）科学研究

主持和参与的主要项目/课题

•国家级青年人才计划，2015-2018，主持

•政府间国际科技创新合作重点专项项目，基于解吸电喷雾飞行时间质谱技术的海洋大气研究，2017/01-2019/12，已结题，主持

•国家自然科学基金委员会, 专项项目, 22442028, 专题研讨类：大气环境化学过程中的多介质相互作用研讨会, 2025, 在研, 主持

•国家自然科学基金委员会, 面上项目, 22376028, 大气气溶胶pH的检测及单颗粒内部酸度梯度分布研究, 2024-2027, 在研, 主持

•国家自然科学基金，面上项目，大气中碳酸根自由基的生成及其氧化潜势，2020/01-2023/12，已结题，主持

•国家自然科学基金面上项目，大气气溶胶表面非均相反应的组份间协同作用机制研究，2017/01-2020/12，已结题，主持

•欧盟FP7框架玛丽居里研究基金，Marie Curie Intra-European Fellowship，2012/8-2014/7，已结题，主持

（4）教研成果

代表性论文：

1.    Yang, L., Liu, Y., Ge, Q., Wang, J., Wang, R., You, W., Wang, W., Wang, T., & Zhang, L. (2025). Atmospheric hydroxyl radical route revealed: Interface-mediated effects of mineral-bearing microdroplet aerosol. Journal of the American Chemical Society, 147(4), 3371–3382.

2.    Wang, W., Liu, Y., Wang, T., Ge, Q., Li, K., You, W., Wang, L., Xie, L., Fu, H., Chen, J., & Zhang, L. (2024). Significantly accelerated photosensitized formation of atmospheric sulfate at air-water interface of microdroplet. Journal of the American Chemical Society, 146(10), 6580.

3.    Gong, K., Ao, J., Li, K., Liu, L., Liu, Y., Xu, G., Wang, T., Cheng, H., Wang, Z., Zhang, X., Wei, H., George, C., Mellouki, A., Herrmann, H., Wang, L., Chen, J., Ji, M., Zhang, L., & Francisco, J. S. (2023). Imaging of pH distribution inside individual microdroplet by stimulated Raman microscopy. Proceedings of the National Academy of Sciences, 120, e2075379176.

4.    Ge, Q., Liu, Y., Li, K., Xie, L., Ruan, X., Wang, W., Wang, L., Wang, T., You, W., & Zhang, L. (2023). Significant acceleration of photocatalytic CO2 reduction at the gas‐liquid interface of microdroplets. Angewandte Chemie International Edition, e202304189.

5.    Liu, Y., Ge, Q., Wang, T., Zhang, R., Li, K., Gong, K., Xie, L., Wang, W., Wang, L., You, W., Ruan, X., Shi, Z., Han, J., Wang, R., Fu, H., Chen, J., Chan, C. K., & Zhang, L. (2024). Strong electric field force at the air/water interface drives fast sulfate production in the atmosphere. Chem, 10(1), 330–351.

6.    Liu, Y., Li, K., Ge, Q., Wang, L., You, W., Gong, K., Ao, J., Xie, L., Wang, W., Yang, L., Wang, R., Wang, J., Wang, L., Ma, M., Huang, T., Wang, T., Ji, M., Fu, H., Chen, J., & Zhang, L. (2025). Interfacial electric fields transform brown carbon formation: Accelerate radical coupling toward strong light-absorbing products. Journal of the American Chemical Society. Advance online publication. https://doi.org/10.1021/jacs.5c08398

7.    Li, K., You, W., Zhu, Y., Wang, W., Wang, L., Liu, Y., Ge, Q., Wang, T., Wang, R., Ruan, X., Cheng, H., & Zhang, L. (2025). Strong electric fields on water microdroplets enable near-unity selectivity in H2O2 photosynthesis. Journal of the American Chemical Society, 147(40), 36136–36145. 

8.    Ge, Q., Liu, Y., You, W., Li, Y., Wang, W., Yang, L., Xie, L., Li, K., Wang, L., Ma, M., Wang, R., Wang, J., Huang, T., Wang, T., Ruan, X., Ji, M., & Zhang, L. (2025). Substantially improved efficiency and selectivity of carbon dioxide reduction by superior hydrated electron in microdroplet. Science Advances, 11(41), eadx5714. 

9.    Jones, R. R., Kerr, J. F., Kwon, H., Clowes, S. R., Ji, R., Petronijevic, E., Zhang, L., Pantoș, G. D., Smith, B., Batten, T., Fischer, P., Wolverson, D., Andrews, D. L., & Valev, V. K. (2024). Chirality conferral enables the observation of hyper-Raman optical activity. Nature Photonics, 18, 982–989.

10.Wang, T., Kalalian, C., Wang, X., Li, D., Perrier, S., Chen, J., Domine, F., Zhang, L., & George, C. (2024). Photoinduced Evolutions of Permafrost-Derived Carbon in Subarctic Thermokarst Pond Surface Waters. Environmental Science & Technology, *58*(39), 17429–17440.

11.Ruan, X., Ao, J., Ma, M., Jones, R. R., Liu, J., Li, K., Ge, Q., Xu, G., Liu, Y., Wang, T., Xie, L., Wang, W., You, W., Wang, L., Valev, V. K., Ji, M., & Zhang, L. (2024). Nanoplastics Detected in Commercial Sea Salt. Environmental Science & Technology, *58*(21), 9091–9101.

12.Xie, L., Luo, S., Liu, Y., Ruan, X., Gong, K., Ge, Q., Li, K., Valev, V. K., Liu, G., & Zhang, L. (2023). Automatic Identification of Individual Nanoplastics by Raman Spectroscopy Based on Machine Learning. Environmental Science & Technology, *57*(46), 18203–18214.

13.Wang, T., Kalalian, C., Fillion, D., Perrier, S., Chen, J., Domine, F., Zhang, L., & George, C. (2023). Sunlight Induces the Production of Atmospheric Volatile Organic Compounds (VOCs) from Thermokarst Ponds. Environmental Science & Technology, *57*(45), 17363–17373.

14.Li, K., You, W., Wang, W., Gong, K., Liu, Y., Wang, L., Ge, Q., Ruan, X., Ao, J., Ji, M., & Zhang, L. (2021). Significantly Accelerated Photochemical Perfluorooctanoic Acid Decomposition at the Air-Water Interface of Microdroplets. Environmental Science & Technology, *57*(50), 21448–21458.

15.Xu, G., Cheng, H., Jones, R., Feng, Y., Gong, K., Li, K., Fang, X., Tahir, M. A., Valev, V. K., & Zhang, L. (2020). Surface-Enhanced Raman Spectroscopy Facilitates the Detection of Microplastics <1 μm in the Environment. Environmental Science & Technology, *54*(24), 15594–15603.

16.Wang, T., Liu, Y., Cheng, H., Yang, Y., Feng, Y., Zhang, L., Fu, H., & Chen, J. (2020). Photochemical Oxidation of Water-Soluble Organic Carbon (WSOC) on Mineral Dust and Enhanced Organic Ammonium Formation. Environmental Science & Technology, *54*(24), 15631–15642.

17.Fu, Y., Kuppe, C., Valev, V. K., Fu, H., Zhang, L., & Chen, J. (2017). Surface-Enhanced Raman Spectroscopy: A Facile and Rapid Method for the Chemical Component Study of Individual Atmospheric Aerosol. Environmental Science & Technology, *51*(11), 6260–6267.