1.       环境光学测量技术研制及其应用，如臭氧光化学生成速率、OH自由基总反应活性、大气颗粒物对过氧自由基摄取系数等的测量方法及其应用；

2.       臭氧污染形成机制及其环境影响效应研究；

3.       大气颗粒物对过氧自由基摄取系数的测量及其环境影响效应研究；

4.       大气颗粒物中活性氧的含量、来源、转化机制及其健康影响效应研究。

部分发表文章列表：

(*为通讯作者，^#为共同一作)

[1] J. Zhou*, K. Sato, Y. Bai, Y. Fukusaki,Y. Kousa , S. Ramasamy, A. Takami, A. Yoshino,  T. Nakayama, Y. Sadanaga, Y. Nakashima, J. Li, K. Murano, N. Kohno, Y. Sakamoto &Y. Kajii*: Kinetics and impacting factors of HO₂ uptake onto submicron atmospheric aerosols during the 2019 Air QUAlity Study (AQUAS) in Yokohama, Japan. Atmos. Chem. Phys., 21(16): 12243-12260, 2021.

[2] Y. Hao^#, J. Zhou*^#, P. Wang, Y. Yang, S. Huangfu, Y. Li, X. B., C. Zhang, A. Liu,Y. Wu, Y. Zhou, S. Yang, Y. Peng, J. Qi, X. He, X. Song, Y. Chen, B. Yuan* & M. Shao: Measuring and modeling investigation of the net photochemical ozone production rate via an improved dual-channel reaction chamber technique. Atmos. Chem. Phys., 23(17): 9891-9910, 2023.

[3] J. Zhou*, Y. Fukusaki, K. Murano, T. Gautam, Y. Bai, Y. Inomata, H. Komatsu, M. Takeda, B. Yuan, M. Shao, Y. Sakamoto & Y. Kajii*: Investigation of HO₂ uptake mechanisms onto multiple-component ambient aerosols collected in summer and winter time in Yokohama, Japan. J. Environ. Sci., 137: 18-29, 2024.

[4] J. Zhou*^#, W. Wang^#, Y. Wu, C. Zhang, A. Liu, Y. Hao, X.-B. Li & M. Shao: Development and application of a nitrogen oxides analyzer based on the Cavity Attenuated Phase Shift (CAPS) technique. J. Environ. Sci., 2023.

[5]J. Zhou, E. A. Bruns, P. Zotter, G. Stefenelli, A. Prévôt, U. Baltensperger, I. EI-Haddad, J. Dommen*: Development, characterization and first deployment of an improved online reactive oxygen species analyzer. Atmos. Meas. Tech., 11, 65-80, 2018.

[6]J. Zhou, P. Zotter, E. A. Bruns, D. Bhattu, G. Stefenelli, D. Bhattu, S. Brown, N. Marchand, A. Bertrand, H. Lamkaddam, J. G. Slowik, A.S.H Prévôt, U. Baltensperger, T. Nussbaumer, I. El-Haddad & J. Dommen*: Particle-bound reactive oxygen species (PB-ROS) emissions and formation pathways in wood smoke under different burning and aging conditions. Atmos. Chem. Phys., 18, 6985-7000, 2018.

[7] J. Zhou, M. Elser, M. Krapf, R. Fröhlich, D. Bhattu, G. Stefenelli, P. Zotter, E. A. Bruns, S. M. Pieber, H. Ni, Q. Y. Wang, Y. Wang, Y. Zhou, J.-J. Cao, M. Xiao, J. G. Slowik, S. Brown, L. E. Cassagnes, K. R. Daellenbach, T. Nussbaumer, M. Geiser, A.S.H. Prévôt, I. El-Haddad, R.-J. Huang*, U. Baltensperger & J. Dommen*: Predominance of secondary Organic aerosol to particle-bound reactive oxygen species activity in fine ambient aerosol. Atmos. Chem. Phys., 19, 14703–14720, 2019.

[8] J. Zhou*, M. Kentaro, N. Kohno, Y. Sakamoto, Y. Kajii*: Real-time quantification of the total HO₂ reactivity of ambient air and HO₂ uptake kinetics onto ambient aerosols in Kyoto (Japan), Atmos. Environ., 223,117189,2020.

[9] J. Zhou, J. Gao*, Y. Liu, K. Ba, R. Zhang: Removal of fluoride from water by five Submerged plants. Bull. Environ. Contam. Toxicol., 89, 395–399, 2012.

[10] J. Zhou, Y. Liu, J. Gao*, R. Zhang, Z. Zhang, N. Sugiura: Contaminant removal performances on domestic sewage using modified anoxic/anaerobic/oxic process and micro-electrolysis, Environ. Technol., 34, 2773-2779, 2013.

[11]J. Zhou, G. Liu, W. Huang, J. Gao*, Z. Wang, R. Zhang: Contaminant removal performances on domestic sewage using modified Merger Johkaso, Technol. Water Treat., 38, 103-107. 2012.

[12] X. Guan^#, J. Zhou^#, N. Ma, X. Chen, J. Gao, R. Zhang: Studies on modified conditions of bio-char and the mechanism for fluoride removal, Desalin. Water Treat., 55: 440-447, 2015.

[13] D. Bhattu, P. Zotter, J. Zhou, G. Stefenelli, F. Klein, A. Bertrand, B. Temime-Roussel, N. Marchand, J.G. Slowik, U. Baltensperger, A.S.H. Prévôt, T. Nussbaumer, I. El Haddad, J. Dommen*: Effect of stove technology and combustion conditions on gas and particulate emissions from residential biomass combustion. Environ. Sci. Technol., 53, 2209-2219, 2019.

[14] M. G. Perrone*,J. Zhou,M. Malandrino, G. Sangiorgi, C. Rizzi, L. Ferrero, J. Dommen, E. Bolzacchini: PM chemical composition and oxidative potential of the soluble fraction of particles at two sites in the urban area of Milan, Northern Italy. Atmos. Environ., 128, 104-113, 2016.

[15] Y. Sakamoto, J. Zhou, N. Kohno, M. Nakagawa, J. Hirokawa & Y. Kajii: Kinetics study of OH uptake onto deliquesced NaCl particles by combining laser photolysis and laser-induced fluorescence. J. Phys. Chem. Lett., 9, 4115-4119, 2018.

[16] W. Wang ^#, J. Qi ^#, J. Zhou, B. Yuan*, Y. Peng, S. Wang, S. Yang, J. Williams, V. Sinha, and M. Shao: The improved comparative reactivity method (ICRM): measurements of OH reactivity under high-NOx conditions in ambient air, Atmos. Meas. Tech., 14, 2285-2298, 2021.

[17] S.Yang, B. Yuan*, Y. Peng, S. Huang , W. Chen, W. Hu , C. Pei , J. Zhou , D. Parrish,   W. Wang, X. He, C. Cheng, X. B.Li, X. Yang, Y. Song, H. Wang, J. Qi, B. Wang, C. Wang, C. Wang, Z. Wang, T.  Li, E. Zheng, S. Wang, C. Wu, M. Cai, C. Ye, W. Song, P. Cheng, D. Chen, X. Wang, Z. Zhang, X. Wang, J. Zheng, and M. Shao*: The formation and mitigation of nitrate pollution: comparison between urban and suburban environments, Atmos. Chem. Phys., 22, 4539-4556, 2022.

[18] N. Kohno, J. Zhou, J. Li, M. Takemura, N. Ono, Y. Sadanaga, Y. Nakashima, K. Sato, S. Kato, Y. Sakamoto, & Y. Kajii: Impacts of missing OH reactivity and aerosol uptake of HO₂ radicals on tropospheric O₃ production during the AQUAS-Kyoto summer campaign in 2018. Atmos. Environ., 281: 119130, 2022.

1.       国家自然科学基金（青年项目），大气臭氧光化学生成速率与生成敏感性的直接测量及其应用，项目编号：42305096，国家自然科学基金委，主持；

2.       广东省重点领域研发计划项目，臭氧污染快速预警及精准应对关键技术研发及应用示范，项目编号：2020B1111360003，广东省科学技术厅，课题负责人；

3.       广东省自然科学基金（面上项目），大气颗粒物对过氧自由基摄取系数的直接测量及其应用，项目编号：2414050001067，广东省基础与应用基础基金委员会，主持；

4.       广东省自然科学基金（青年项目），新型臭氧生成速率检测仪的搭建，表征与应用，项目编号：2020A1515110526，广东省基础与应用基础基金委员会，主持；

5.       国家重点研发计划项目，大气活性含碳成分来源、转化及环境效应，项目编号：2023YFC3706200, 中国21世纪议程管理中心，项目骨干，参与。

含碳组分大气环境行为及效应研究团队