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IntroductionDr. Zhou-jun Wang is a Professor in College of Chemical Engineering at Beijing University of Chemical Technology (BUCT). He is Head of the Department of Chemical Technology and Deputy Director of Beijing Key Laboratory of Energy Environmental Catalysis. Before he joined BUCT, he was educated at Tianjin University, Texas A & M University College Station), and Dalian Institute of Chemical Physics (the Chinese Academy of Sciences). He was a visiting scholar at the National Institute for Materials Science (NIMS) during 2017–2018. His research interests focus on energy and environmental catalysis based on thermal and photo-thermo processes, especially in the field of carbon dioxide conversion. He served as Guest Editors in Catalysis Today, Topics in Catalysis and Greenhouse Gases: Science and Technology. He was selected as a Young Yangtze River Scholar. EducationWork ExperienceSocial PositionSocial ActivitiesResearchTeachingPostgraduatesFundingVertical ProjectHorizontal ProjectPublications1. H. Song, X. Meng, Z.-j. Wang*, H. Liu, J. Ye*, Solar-energy-mediated methane conversion, Joule, 3 (2019) 1606-1636. 2. Z.-j. Wang, H. Song, H. Liu, J. Ye*, Coupling of solar energy and thermal energy for carbon dioxide reduction: Status and prospects, Angew. Chem. Int. Ed., 59 (2020) 8016-8035. 3. G. Xie, R. Jin, P. Ren*, Y. Fang*, R. Zhang, Z.-j. Wang*, Boosting CO2 hydrogenation to methanol by adding trace amount of Au into Cu/ZnO catalysts, Appl. Catal. B Environ., 324 (2023) 122233. 4. Z.-j. Wang, H. Song, H. Pang, Y. Ning, T. D. Dao, Z. Wang, H. Chen, Y. Weng, Q. Fu, T. Nagao, Y. Fang*, J. Ye*, Photo-assisted methanol synthesis via CO2 reduction under ambient pressure over plasmonic Cu/ZnO catalysts, Appl. Catal. B Environ., 250 (2019) 10-16. 5. Y. Liu*, X. Gong, R. He, Z. Han, J. Chen, B. Feng, X. Xu, A. Xing*, R. Jin, P. Ren, B. Wang, Z.-j. Wang*, Stable three-dimensional macroporous iron-foam catalyst for direct conversion of CO2 to olefins, ACS Catal., 14 (2024) 12425-12436. 6. L. Luo#, Z.-j. Wang#, X. Xiang*, D. Yan*, J. Ye*, Selective activation of benzyl alcohol coupled with photoelectrochemical water oxidation via a radical relay strategy, ACS Catal., 10 (2020) 4906-4913. 7. G. Xie, X. Bai, Y. Man, P. Ren, R. Jin, R. Zhang, K. Ostrikov, Z.-j. Wang*, Q. Yang*, High-performance Al-doped Cu/ZnO catalysts for CO2 hydrogenation to methanol: MIL-53(Al) source-enabled oxygen vacancy engineering and related promoting mechanisms, Chem. Eng. J., 480 (2024) 148195. 8. L. Su, L. Luo, H. Song, Z. Wu, W. Tu*, Z.-j. Wang*, J. Ye*, Hemispherical shell-thin lamellar WS2 porous structures composited with CdS photocatalysts for enhanced H2 evolution, Chem. Eng. J., 388 (2020) 124346. 9. G. Xie, X. Wang, X. Li, Y. Fang*, R. Zhang, Z.-j. Wang*, Oxygen vacancy-boosted thermocatalytic CO2 hydrogenation: Engineering strategies, promoting effects and mediating mechanisms, J. Energy Chem., 99 (2024) 393-408. 10. J. Sun, Y. Wang, H. Zou, X. Guo, Z.-j. Wang*, Ni catalysts supported on nanosheet and nanoplate γ-Al2O3 for carbon dioxide methanation, J. Energy Chem., 29 (2019) 3-7. AwardsPatentHonor RewardAdmissions Information |