1)Chuan Shi, Yaying Ji, Uschi M. Grahama, Gary Jacobs, Mark Crocker*, Zhaoshun Zhang, Yu Wang, Todd J. Toops, “NOx storage and reduction properties of model ceria-based lean NOx trapcatalysts”, Applied Catalysis B: Environmental, 2012, 119-120: 183-196
5)Shi Chuan*, Xu Li, Ai-Min Zhu, Zhang Yuzhuo, Au Chak Tong, “Copper Oxide Clusters Stabilized by Ceria for CO, C3H6, and NO Abatement”, Chinese Journal of Catalysis, 2012, 33: 1455-1462 (封面文章)
6)Hong-Yu Fan, Chuan Shi, Xiao-Song Li, Shuo Zhang, Jing-Lin Liu, Ai-Min Zhu*, “In-situ plasma regeneration of deactivated Au/TiO2 nanocatalysts during CO oxidation and effect of N2 content”, Applied Catalysis B: Environmental, 2012, 119-120: 49-55
Impact Factor: 5.625 (5-Year Impact Factor:6.052)
7)De-Zhi Zhao, Chuan Shi, Xiao-Song Li, Ai-Min Zhu*, Ben W.-L. Jang*, “Enhanced effect of water vapor on complete oxidation of formaldehyde in air with ozone over MnOx catalysts at room temperature”, Journal of Hazardous Materials, 2012, 239: 362-369
8)Lan-Bo Di, Chuan Shi, Xiao-Song Li, Jing-Lin Liu, Ai-Min Zhu*, “Uniformity, structure and photocatalytic activity of TiO2 films deposited by 2 atmospheric-pressure linear cold plasma”, Chemical Vapor Deposition, 2012, Accepted
10) Zhao Dezhi, Ding Tianying, Li Xiaosong, Liu Jinglin, Shi Chuan, Zhu Aimin*, “Ozone catalytic oxidation at room temperature of HCHO in air over MnOx”, Chinese Journal of Catalysis, 2012, 33: 396-401
(11) Zhao De-Zhi; Li Xiao-Song; Shi Chuan; Fan Hong-Yu; Zhu Ai-Min*, Low-concentration formaldehyde removal from air using a cycled storage-discharge (CSD) plasma catalytic process” CHEMICAL ENGINEERING SCIENCE, 2011, 66(17), 3922-3929.
(13)Hong-Yu Fan, Xiao-Song Li, Chuan Shi, De-Zhi Zhao, Jing-Lin Liu, Yan-Xia Liu, Ai-Min Zhu*, “Plasma catalytic oxidation of stored benzene in a cycled storage-discharge (CSD) process: catalysts, reactors and operation conditions”, Plasma Chemistry and Plasma Processing, 2011, 31: 799-810
Impact Factor: 1.819 .
(14) Xiaomei Chen, Aimin Zhu, C. T. Au, Chuan Shi* “Enhanced Low-Temperature Activity of Ag-Promoted Co-ZSM-5 for the CH4-SCR of NO”, CATALYSIS LETTERS 2011 141 (1) 207-212 .
Impact Factor: 1.974.
(15) Li Xiao-Song; Zhu Bin; Shi Chuan, Xu Yong; Zhu Ai-Min*. “Carbon Dioxide Reforming of Methane in Kilohertz Spark-Discharge Plasma at Atmospheric Pressure”, AICHE JOURNAL, 2011, 57(10), 2854-2860.
Impact Factor: 2.215.
(16) Xiaomei Chen, Aimin Zhu, C. T. Au, Xuefeng Yang,, Chuan Shi* “The Role of Active Sites of CoH-ZSM-5 Catalysts for the C2H4-SCR of NO” CATALYSIS LETTERS 2010 135 (3-4) 182-189
Impact Factor: 1.974.
(17) An-Jie Zhang, Ai-Min Zhu, Jun Guo, Yong Xu and Chuan Shi* “Conversion of greenhouse gases into syngas via combined effects of discharge activation and catalysis” CHEMICAL ENGINEERING JOURNAL 2010, 156 (3) 601-606
Impact Factor: 3.171.
(18)Jun Guo, Anjie Zhang, Aimin Zhu, Yong Xu, Chatktong Au, Chuan Shi*, “A Carbide Catalyst Effective for the Dry Reforming of Methane at Atmospheric Pressure”, ACS Symposium Series, Advances in CO2 Conversion and Utilization, American Chemistry Society: Washington, 2010, pp. 181-196.
(19)Fan, H. Y., C. Shi, X. S. Li, X. F. Yang, Y. Xu, and A. M. Zhu, Low-temperature NO (x) Selective Reduction by Hydrocarbons on H-Mordenite Catalysts in Dielectric Bar rier Discharge Plasma. Plasma Chemistry and Plasma Processing, 2009. 29(1): p. 43-53.
Impact Factor: 1.819 .
(20) Xiaomei Chen , Aimin Zhu, Chuan Shi* “The Nature of Active Sites of Co/Al2O3 for the Selective Catalytic Reduction of NO with C2H4”, Catalysis Letters, 2009, 133 (1-2) 134-141.
Impact Factor: 1.974.
(21) Hong-Yu Fan, Chuan Shi, Xiao-Song Li, De-Zhi Zhao, Yong Xu and Ai-Min Zhu, “High-efficiency plasma catalytic removal of dilute benzene from air”, J. Phys. D: Appl. Phys. 42 (2009) 225105
Impact Factor: 2.332.
(22) Zhiwei Yao, Aimin Zhu, C. T. Au, Chuan Shi*, “Redox Properties of cobalt nitrides for NO dissociation and reduction”, Catalysis Letters, 2009, 130 (1-2) 63-71..
Impact Factor: 1.974.
(23) Xiao-Mei Chen, Xue-Feng Yang, Ai-Min Zhu, Hong-Yu Fan, Xin-Kui Wang, Qin Xin, Xin-Rui Zhou, Chuan Shi*,In situ DRIFTS study on the partial oxidation of ethylene over Co-ZSM-5 catalyst,Catalysis Communications,10 (2009) 428-432.
Impact Factor: 2.906.
(24) Zhiwei Yao, Chuan Shi*, “Development of a catalytic cycle in molybdenum carbide catalyzed NO/CO reaction”, Catalysis Letters, 2009, 130 (1-2) 239-245.
Impact Factor: 1.974.
(25) Xiaoqing Cheng, Aimin Zhu, Yuzhuo Zhang, Yong Wang, C.T. Au, Chuan Shi*, “A combined DRIFTS and MS study on reaction mechanism of NO reduction by CO over NiO/CeO2 catalyst”, Applied Catalysis B: Environmental, 2009, 90 (3-4) 395-404.
Impact Factor: 5.438 .
(26) Xiaomei Chen , Xuefeng Yang , Aimin Zhu, C.T. Au , Chuan Shi*, “In situ DRIFTS study during C2H4-SCR of NO over Co-ZSM-5 ”, Journal of Molecular Catalysis A: Chemical, 2009, 312(1-2), 31-39.
Impact Factor: 3.16.
(27) Di, L. B., X. S. Li, C. Shi, Y. Xu, D. Z. Zhao, and A. M. Zhu, Atmospheric-pressure plasma CVD of TiO2 photocatalytic films using surface dielectric barrier discharge. Journal of Physics D-Applied Physics, 2009 42(3) 032001.
Impact Factor: 2.332 .
(28)Li, X. S., C. K. Lin, C. Shi, Y. Xu, Y. N. Wang, and A. M. Zhu, “Stable kilohertz spark discharges for high-efficiency conversion of methane to hydrogen and acetylene”. Journal of Physics D-Applied Physics, 2008. 41(17)175203.
Impact Factor: 2.332
(29)Wang, K. J., X. S. Li, H. Wang, C. Shi, Y. Xu, and A. M. Zhu, “Oxygen-Free Conversion of Methane to Ethylene in a Plasma-Followed-by-Catalyst (PFC) Reactor”. Plasma Science & Technology, 2008. 10(5): p. 600-604.
Impact Factor: 0.553
(30)Yao, Z. W., A. J. Zhang, Y. Li, Y. Z. Zhang, X. Q. Cheng, and C. Shi, An investigation of the thermal stability, crystal structure and catalytic properties of bulk and alumina-supported transition metal nitrides. Journal of Alloys and Compounds, 2008. 464(1-2): p. 488-496.
Impact Factor: 2.134
(31) Yong Wang, Aimin Zhu, Yuzhuo Zhang, C.T. Au, Xuefeng Yang, Chuan Shi* “Catalytic reduction of NO by CO over NiO/CeO2 catalystin stoichiometric NO/CO and NO/CO/O2 reaction”, Applied Catalysis B: Environmental 81 (2008) 141–149.
Impact Factor: 5.438.
(32) Xiao-Song Li, Chuan Shi, Yong Xu, Xiu-Ling Zhang, Kang-Jun Wang, and Ai-Min Zhu, “Pulsed streamer discharge plasma over Ni/ZSM-5 catalysts for methane conversion to Aromatics at atmospheric pressure.” Plasma Processes and Polymers, 2007, 4:15-18.
Impact Factor: 2.447.
(33)Hongyan Zhang, Aimin Zhu, Xinkui Wang, Yong Wang, Chuan Shi*, “Catalytic performance of Ag-Co/CeO2 catalyst in NO-CO and NO-CO-O2 system.” Catal. Commun. 2007, 8: 612-8.
Impact Factor: 2.906.
(34) Xiao-Song Li, Chuan Shi, Yong Xu, Kang-Jun Wang and Ai-Min Zhu, “A novel process for high yield of aromatics from oxygen-free conversion of methane: combining plasma with Ni/HZSM-5 catalysts”, Green Chemistry, 2007, 9: 647-653.
Impact Factor: 6.056.
(35) Niu, J. H., A. M. Zhu, C. Shi, H. Y. Fan, X. M. Chen, and X. F. Yang, “The reactions and composition of the surface intermediate species in the selective catalytic reduction of NOx, with ethylene over Co-ZSM-5”. Research on Chemical Intermediates, 2007. 33(6): p. 549-566.
Impact Factor :0.715 .
(36)Long-Hui Nie, Chuan Shi, Yong Xu, Qing-Hao Wu, Ai-Min Zhu, “Atmospheric cold plasma for synthesizing nanocrystalline anatase TiO2 using dielectric barrier discharge”, Plasma Processes and Polymers, 2007, 4:574-582.
Impact Factor: 2.447.
(37) Zhiwei Yao, Aimin Zhu, Jing Chen, Xinkui Wang, C.T. Au, Chuan Shi*, “Synthesis, characterization and activity of alumina-supported cobalt nitride for NO decomposition”, Journal of Solid State Chemistry, 2007, 180: 2635-2640.
Impact Factor: 2.484.
(38) Zhang, X. L., L. H. Nie, Y. Xu, C. Shi, X. F. Yang, and A. M. Zhu, “Plasma oxidation for achieving supported TiO2 photocatalysts derived from adsorbed TiCl4 using dielectric barrier discharge”. Journal of Physics D-Applied Physics, 2007. 40(6): p. 1763-1768.
Impact Factor: 2.332 .
(39) Zhu, A. M., L. H. Nie, Q. H. Wu, X. L. Zhang, X. F. Yang, Y. Xu, and C. Shi, Crystalline, uniform-sized TiO2 nanosphere films by a novel plasma CVD process at atmospheric pressure and room temperature. Chemical Vapor Deposition, 2007. 13(4): p. 141.