On the Role of Vanadia Species for VOx/SiO2 in the Selective Oxidation of Methane

摘要/Abstract

摘要： Various VOx/SiO2 catalysts were prepared by the methods of physical mixing, conventional wetness impregnation and ultrasonication-assistant impregnation. The catalysts were characterized by XRD, UV-Vis DRS, Raman, TPR, ESR and TPSR techniques and the nature of the vanadium species were correlated to their catalytic performance in the reaction of direct conversion of methane to formaldehyde. It is concluded that highly dispersed monomeric and low oligomeric vanadia species are formed on the sample prepared with both traditional wetness impregnation method and ultrasonication-assistant impregnation, whereas in the latter case, the amount of oligomeric vanadia species is much smaller. The V2O5 microcrystallines are the dominant species on the material prepared by physical mixing method. During the selective oxidation of methane, VV species are reduced to VIV paramagnetic species and both microcrystalline V2O5 species and oligomeric vanadia species are found to further disperse and transform into tetrahedral vanadia species. Based on the results of UV Raman spectroscopy and TPSR, CO2 is suggested to be formed via two different routes, in which one is from the sequence reaction of CH4 → HCHO →CO → CO2 over monomeric vanadia species, and the other is from the direct oxidation of methane to CO2 over oligomeric vanadia species. Oligomeric vanadia species is more active than monomeric vanadia species for methane activation.

关键词: methane activation, formaldehyde, VOx/SiO2, TPSR, TPR, UV Raman

Abstract: Various VOx/SiO2 catalysts were prepared by the methods of physical mixing, conventional wetness impregnation and ultrasonication-assistant impregnation. The catalysts were characterized by XRD, UV-Vis DRS, Raman, TPR, ESR and TPSR techniques and the nature of the vanadium species were correlated to their catalytic performance in the reaction of direct conversion of methane to formaldehyde. It is concluded that highly dispersed monomeric and low oligomeric vanadia species are formed on the sample prepared with both traditional wetness impregnation method and ultrasonication-assistant impregnation, whereas in the latter case, the amount of oligomeric vanadia species is much smaller. The V2O5 microcrystallines are the dominant species on the material prepared by physical mixing method. During the selective oxidation of methane, VV species are reduced to VIV paramagnetic species and both microcrystalline V2O5 species and oligomeric vanadia species are found to further disperse and transform into tetrahedral vanadia species. Based on the results of UV Raman spectroscopy and TPSR, CO2 is suggested to be formed via two different routes, in which one is from the sequence reaction of CH4 → HCHO →CO → CO2 over monomeric vanadia species, and the other is from the direct oxidation of methane to CO2 over oligomeric vanadia species. Oligomeric vanadia species is more active than monomeric vanadia species for methane activation.

Key words: methane activation, formaldehyde, VOx/SiO2, TPSR, TPR, UV Raman

Shaojun Miao;Ding Ma;Qingjun Zhu;Heng Zheng;Guoqing Jia;Shutian Zhou;Xinhe Bao. On the Role of Vanadia Species for VOx/SiO2 in the Selective Oxidation of Methane[J]. 能源化学(英文), 2005, 14 (2): 77-87.

Shaojun Miao;Ding Ma;Qingjun Zhu;Heng Zheng;Guoqing Jia;Shutian Zhou;Xinhe Bao. On the Role of Vanadia Species for VOx/SiO2 in the Selective Oxidation of Methane[J]. Journal of Energy Chemistry, 2005, 14 (2): 77-87.

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[3]	Zhiming Gao, Yuanyuan Gong, Qiang Zhang, Hao Deng, Yong Yue. Preferential oxidation of CO in excess H₂ over the CeO₂/CuO catalyst：Effect of initial support[J]. 能源化学(英文), 2014, 23(4): 475-482.
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[5]	John N. Armor* . Emerging importance of shale gas to both the energy & chemicals landscape[J]. 能源化学(英文), 2013, 22(1): 21-26.
[6]	Fengsi Liu, Wei Chu*, Wenjing Sun, Ying Xue, Qian Jiang. A DFT study of methane activation on graphite surfaces with vacancy defects [J]. 能源化学(英文), 2012, 21(6): 708-712.
[7]	Zhiming Gao*, Ming Zhou, Hao Deng, Yong Yue . Preferential oxidation of CO in excess H₂ over CeO₂/CuO catalyst: Effect of calcination temperature[J]. 能源化学(英文), 2012, 21(5): 513-518.
[8]	Zhiming Gao*, Huili Li. Tuning surface active oxygen of lanthanum oxide via partial dissolution and regrowth of crystallites[J]. 能源化学(英文), 2011, 20(5): 483-486.
[9]	Bao Agula, Tiezhen Ren, Xu Zhao, Bao Zhaorigetu, Zhongyong Yuan*. Relationship between the reducibility and selectivity of CeMo_xV_1-xO₄ catalysts by kinetic parameters of TPR[J]. 能源化学(英文), 2011, 20(3): 232-236.
[10]	Xiaoping Dai;Changchun Yu*. Effects of pretreatment and reduction on the Co/Al2O3 catalyst for CO hydrogenation[J]. 能源化学(英文), 2008, 17(3): 288-292.
[11]	Kebing Wang;Jie Yao;Yue Wang;Gongying Wang*. Catalytic Systems Containing p-Toluenesulfonic Acid for the Coupling Reaction of Formaldehyde and Methyl Formate[J]. 能源化学(英文), 2007, 16(3): 286-292.
[12]	Liping Zhao;Shengfu Ji;Fengxiang Yin;Zexiang Lu;Hui Liu;Chengyue Li. Catalytic Combustion of Methane over Co1-xMgxO/Al2O3/FeCrAl Monolithic Catalysts[J]. 能源化学(英文), 2006, 15(4): 287-296.
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[14]	Yun Hin Taufiq-Yap. Effect of Cr and Co Promoters Addition on Vanadium Phosphate Catalysts for Mild Oxidation of n-Butane[J]. 能源化学(英文), 2006, 15(2): 144-148.
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