科学研究

代表性论文

近年来发表论文情况

[1] Wang Yongzhao, Zheng Ke, Hu Xiaobo, Zhou Wei, Wei Huxui, Zhao Yongxiang. Y2O3 promoted Co3O4 catalyst for catalytic decomposition of N2O [J]. Mol Catal, 2019, 470:104-111

[2] Li Xiao, Wang Yongzhao, Lv Tinging, Xu Yalin, Zhao Yongxiang. Preparation and characterization of carbon modified Pd-Cu/ palygorskite forroom-temperature CO oxidation under moisture-rich conditions [J]. Catal Surv Asia, 2019, 23:102-109

[3] Wang Yongzhao, Wei Xuhui, Hu Xiaobo, Zhou Wei, Zhao Yongxiang. Effect offormic Acid treatment onthestructure andcatalytic activityofCo3O4 for N2O decomposition [J]. Catal Lett, 2019, 149:1026-1036

[4] Li Haitao(*), Ban Lijun, Wang Zhipeng, Meng Pingfan, Zhang Yin, Wu Ruifang, Zhao Yongxiang(*). Regulation of Cu species in CuO/SiO2 and its structural evolution in ethynylation reaction[J]. Nanomaterials,2019, 9, 842; doi:10.3390/nano9060842.

[5] Li Haitao(*),Zhang Yin, Zhang Hongxi, Qin Xiaoqin, Xu Yalin, Wu Ruifang, Jiang Zheng, Zhao Yongxiang(*). The nature of the deactivation ofhydrothermally stable Ni/SiO2-Al2O3 catalyst in long-time aqueous phasehydrogenation of crude 1,4-butanediol[J]. Chinese Journal of Chemical Engineering,2019. DOI: 10. 1016/j. cjche. 2019. 03. 008.

[6] Wang Zhipeng, Niu Zhuzhu, Hao Quanai,Ban Lijun, Li Haitao, Zhao Yongxiang, Jiang Zhen.Enhancing the ethynylationperformance of CuO-Bi2O3nanocatalysts by tuning Cu-Bi interactions and phase structures[J]. Catalysts, 2019, 9, 35; doi:10.3390/catal9010035.

[7] Zhao Lili, Zhao Jianghong, Wu Tianjie, Zhao Min, Yan Wenjun, Zhang Yin, Li Haitao, Wang Yongzhao, Xiao Tiancun, Zhao Yongxiang. Synergistic Effect of Oxygen Vacancies and Ni Species on Tuning Selectivity of Ni/ZrO2 Catalyst for Hydrogenation of Maleic Anhydride into Succinic Anhydride and γ-Butyrolacetone. Nanomaterials[J], 2019, 9:406

[8] Zhao Lili, Zhang Yin, Wu Tianjie, Zhao Min, Wang Yongzhao, Zhao Jianghong, Xiao Tiancun, Zhao Yongxiang. Tuning Selectivity of Maleic Anhydride Hydrogenation Reaction over Ni/Sc-Doped ZrO2 Catalysts[J], Catalysts , 2019, 9: 366

[9] Li Haitao, Qiu Yuan, Wang Changzhen, Huang Xin, Xiao Tiancun, Zhao Yongxiang(*). Nickel catalysts supported on ordered mesoporous SiC materials for CO2 reforming of methane. Catalysis Today, 2018, 317: 76-85.

[10] Wang Yongzhao, Wang Yongning, Li Xiao, Liu Zhaotie, Zhao Yongxiang. Effect of ultrasonic treatment of palygorskite on the catalytic performance of Pd-Cu/palygorskite catalyst for room temperature CO oxidation in humid circumstances [J]. Environ Technol, 2018, 39(6):780-786

[11] Wang Yongzhao, Hu Xiaobo, Zheng Ke, Wei Xuhui, Zhao Yongxiang. Effect of SnO2 on the structure and catalytic performance of Co3O4 for N2Odecomposition [J]. Catal Commun, 2018, 111:70-74

[12] Wang Yongzhao, Hu Xiaobo, Zheng Ke, Zhang Hongxi, Zhao Yongxiang. Effect of precipitants on the catalytic activity of Co–Cecomposite oxide for N2O catalytic decomposition [J]. React Kinet Mech Cat, 2018, 123:707-721

[13] Wang Yongzhao, Li Xiao, Lv Tingting, Wu Ruifang, Zhao Yongxiang. Effect of precipitants on the catalytic performanceof Pd-Cu/attapulgite clay catalyst for CO oxidationat room temperature and in humid circumstances [J]. React Kinet Mech Cat, 2018, 124:203-216

[14]  Lili Zhao, Yu Huang, Haoyi Chen, Yongxiang Zhao, Tiancun Xiao. Study on the preparation of bimetallic oxide sorbent for mercury removal. Fuel, 2017, 197: 20-27;

[15] Wang Changzhen, Zhang Yin, Wang Yongzhao, Zhao Yongxiang. Comparative Studies of Non-noble Metal Modified Mesoporous M-Ni-CaO-ZrO2 (M?="?Fe," Co, Cu) Catalysts for Simulated Biogas Dry Reforming [J]. Chin J Catal, 2017, 35(1):113-120

[16] Wang Yongzhao, Shi Jing, Wu Ruifang, Li Xiao, Zhao Yongxiang. Room-temperature CO oxidation over calcined Pd-Cu/palygorskite catalysts [J]. Appl Clay Sci, 2016, 119:126-131

[17] Wang Yongzhao, Fan Liyuan, Shi Jing, Li Xiao, Zhao Yongxiang. Effect of preparation method on the catalytic activities of Pd–Cu/APT catalysts for low-temperature CO oxidation [J]. Catal Lett, 2015, 145(7):1429-1435

[18] Wang Yong-zhao, Li Feng-mei, Cheng Hui-min, Fan Li-yuan, Zhao Yong-xiang. A comparative study on the catalytic properties of high Ni-loading Ni/SiO2 and low Ni-loading Ni-Ce/SiO2 for CO methanation[J].J Fuel Chem Technol, 2013, 41(8):972-977

[19] Li, Haitao,Zhao, Yongxiang(*),Gao, Chunguang,Wang, Yongzhao,Sun, Zijin,Liang, Xiaoyuan,Study ondeactivation of Ni/Al2O3 catalyst for liquid phase hydrogenation of crude 1,4-butanediol aqueoussolution,Chemical Engineering Journal,2012,181:501-507.

[20] Li Haitao,Chen Haoran,Zhang Yin,Gao Chunguang,Zhao Yongxiang(*),Preparation and Characterizationof Carbon-Covered Alumina Supported Ni Catalyst and Its Catalytic Performance for Hydrogenation,Chinese Journal of Catalysis,2011,32(1):111-117.

[21] Li, Haitao,Xu, Yalin,Gao, Chunguang,Zhao, Yongxiang(*),Structural and textural evolution ofNi/α-Al2O3 catalyst under hydrothermal conditions,Catalysis Today,2010,158(3-4):475-480.

[22] Peng-Fei Gao, Tie-Ming Zhang, Yong-Zhao Wang, Chun-Guang Gao, Yong-Xiang Zhao. Spaced-amine modified SBA-15: Synthesis and characterization[J]. Mater Lett, 2011, 65:260-263.

[23] Yin Zhang, Li Pan, Chun-Guang Gao, Yong-Zhao Wang, Yong-Xiang Zhao. Preparation of ZrO2-SiO2 mixed oxide by combination of sol-gel and alcohol-aqueous heating method and its application in tetrahydrofuran polymerization[J]. J Sol-Gel Technol, 2010, 56:27-32.

[24] Yong-Zhao Wang, Rui-Fang Wu, Yong-Xiang Zhao. Effect of ZrO2 promoter on structure and catalytic activity of the Ni/SiO2 catalyst for CO methanation in hydrogen-rich gases[J]. Catal Today, 2010, 158: 470-474.

[25] Rui-Fang Wu, Yin Zhang, Yong-Zhao Wang, Chun-Guang Gao, Yong-Xiang Zhao. Effect of ZrO2 promoter on the catalytic activity for CO methanation and adsorption performance of the Ni/SiO2 catalyst[J]. J Fuel Chem Technol, 2009, 37(5), 578-582.

[26] Yong-Zhao Wang, Yong-Xiang Zhao, Chun-Guang Gao, Dian-Sheng Liu. Origin of the high activity and stability of Co3O4 in low-temperature CO oxidation[J]. Catal Lett, 2008, 125:134-138.

[27] Xiao-Dong Hou, Yong-Zhao Wang, Yong-Xiang Zhao. Effect of CeO2 doping on structure and catalytic performance of Co3O4 catalyst for low-temperature CO oxidation[J], Catal Lett, 2008, 123:321-326.

[28] Yong-Zhao Wang, Yong-Xiang Zhao, Chun-Guang Gao, Dian-Sheng Liu. Preparation and catalytic performance of Co3O4catalysts for low-temperature CO oxidation[J], Catal Lett, 2007, 116: 136-141.

[29] C. Wang, et al, Geometric design of a Ni@silica nano-capsule catalyst with superb methane dry reforming stability: enhanced confinement effect over the nickel site anchoring inside a capsule shell with an appropriate inner cavity.Catalysis Science & Technology, 2018, 8, 4877–4890.(Cover)

[30] H. Li, Y. Qiu, C. Wang, et al, Nickel catalysts supported on ordered mesoporous SiC materials for CO2 reforming of methane. Catalysis Today 317 (2018) 76–85

[31] C. Wang, Y. Zhang, Y. Wang, Y. Zhao, Comparative Studies of Non-noble Metal Modified Mesoporous M-Ni-CaO-ZrO2 (M="Fe," Co, Cu) Catalysts for Simulated Biogas Dry Reforming, Chinese Journal of Chemistry, 35 (2017) 113-120.

[32] C. Wang, N. Sun, N. Zhao, W. Wei, Y. Zhao, Template-free preparation of bimetallic mesoporous Ni-Co-CaO-ZrO2 catalysts and their synergetic effect in dry reforming of methane, Catalysis Today, 281 (2017) 268-275.

[33] C. Wang, N. Sun, W. Wei, Y. Zhao, Carbon intermediates during CO2 reforming of methane over Ni-CaO-ZrO2 catalysts: A temperature-programmed surface reaction study, Int. J. Hydrog. Energy, 41 (2016) 19014-19024.

[34] C. Wang, N. Sun, N. Zhao, W. Wei, Y. Sun, C. Sun, H. Liu, C.E. Snape, Coking and deactivation of a mesoporous Ni-CaO-ZrO2 catalyst in dry reforming of methane: A study under different feeding compositions, Fuel, 143 (2015) 527-535.

[35] C. Wang, N. Sun, N. Zhao, W. Wei, J. Zhang, T. Zhao, Y. Sun, C. Sun, H. Liu, C.E. Snape, The Properties of Individual Carbon Residuals and Their Influence on The Deactivation of Ni-CaO-ZrO2 Catalysts in CH4 Dry Reforming, Chemcatchem, 6 (2014) 640-648.

[36] C. Wang, N. Sun, M. Kang, X. Wen, N. Zhao, F. Xiao, W. Wei, T. Zhao, Y. Sun, The bi-functional mechanism of CH4 dry reforming over a Ni-CaO-ZrO2 catalyst: further evidence via the identification of the active sites and kinetic studies, Catalysis Science & Technology, 3 (2013) 2435-2443.

[37] C. Wang, L. Si, H. Li, X. Wen, N. Sun, N. Zhao, W. Wei, Y. Sun, Template-free one-pot synthesis of mesoporous Ni-CaO-ZrO_2 catalyst and its application in CH_4-CO_2 reforming, Journal of Fuel Chemistry and Technology, 41 (2013) 1204-1209.

[38]Ma, H.; Chen, Y.-Y.; Wang,S.; Wei, Z.-H.; Qin, Z.-F.; Dong, M.; Li, J.-F.; Fan, W.-B. and Wang, J.-G.; Reaction mechanism for the conversion of methanol to olefins over H-ITQ-13 zeolite: A density functional theory study;Catal. Sci. Technol.;2018,8, 521-533

[39]Ma, H.; Chen, Y.-Y.; Wei,Z.-H.; Wang, S.; Qin, Z.-F.; Dong, M.; Li, J.-F.; Wang, J.-G. and Fan, W.-B.; DFT Studies on the Reaction Mechanism for Direct Cyclization of Linear C5, C6 and C7 Alkenes over H-ITQ-13 Zeolite; ChemPhysChem;2018, 19, 496-503

[40] Pengfei Gao, Tieming Zhang, Yongzhao Wang, Chunguang Gao, Yongxiang Zhao*, Spaced-amine modi?ed SBA-15: Synthesis and characterization,Materials Letters, 2011, 65: 260–263


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