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RSC Adv

Title:		Enhanced plasma-catalytic decomposition of toluene over Co-Ce binary metal oxide catalysts with high energy efficiency
Author(s):		Bo Z; Zhu J; Yang S; Yang H; Yan J; Cen K;
Address:		"State Key Laboratory of Clean Energy Utilization, Institute for Thermal Power Engineering, College of Energy Engineering, Zhejiang University Hangzhou Zhejiang Province 310027 China huachao@zju.edu.cn +86 571 87952438 +86 571 87953290"
Journal Title:		RSC Adv
Year:		2019
Volume:		20190306
Issue:		13
Page Number:		7447 - 7456
DOI:		10.1039/c9ra00794f
ISSN/ISBN:		2046-2069 (Electronic) 2046-2069 (Linking)
Abstract:		"In-plasma catalysis has been considered as a promising technology to degrade volatile organic compounds. Heterogeneous catalysts, especially binary metal oxide catalysts, play an important role in further advancing the catalytic performance of in-plasma catalysis. This work investigates the toluene decomposition performance over Co-Ce binary metal oxide catalysts within the in-plasma catalysis. Co-Ce catalysts with different Co/Ce molar ratios are synthesized by a citric acid method. Results show that the catalytic activity of Co-Ce catalysts is obviously superior to those of monometallic counterparts. Especially, Co(0.75)Ce(0.25)O (x) catalyst simultaneously realizes highly efficient toluene conversion (with a decomposition efficiency of 98.5% and a carbon balance of 97.8%) and a large energy efficiency of 7.12 g kW h(-1), among the best performance in the state-of-art literature (0.42 to 6.11 g kW h(-1)). The superior catalytic performance is further interpreted by the synergistic effect between Co and Ce species and the significant plasma-catalyst interaction. Specifically, the synergistic effect can decrease the catalyst crystallite size, enlarge the specific surface area and improve the amount of oxygen vacancies/mobility, providing more active sites for the adsorption of surface active oxygen species. Meanwhile, the plasma-catalyst interaction is able to generate the surface discharge and reinforce the electric field strength, thereby accelerating the plasma-catalytic reactions. In the end, the plasma-catalytic reaction mechanism and pathways of toluene conversion are demonstrated"
Keywords:
Notes:		"PubMed-not-MEDLINEBo, Zheng Zhu, Jinhui Yang, Shiling Yang, Huachao Yan, Jianhua Cen, Kefa eng England 2019/03/06 RSC Adv. 2019 Mar 6; 9(13):7447-7456. doi: 10.1039/c9ra00794f. eCollection 2019 Mar 1"