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Determination of Surface V=o sPecies of V2O5 Catalysts During Reaction Condition By Using in-Situ Narp Technique

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NARP (Nitric oxide-Ammonia Rectangular Pulse) technique was applied for the in-situ measurement of the number of surface V=O species of V2O5 catalysts. When V2O5 catalyst was exposed to flowing benzene/O2/N2 mixture gas at 573-673 K, the surface concentration of V=O species decreased and finally reached a steady state which was dependent on the [O2]/[Benzene] ratio in the feed gas. It was confirmed by XPS spectra that the decrease in the surface V=O species is attributed to the reduction of the V2O5 surface. Although calcination of V2O5 at above 873 K reduced the surface concentration of V=O species, it recovered after a cyclic reduction-oxidation treatment at 673 K, which modifies the near-surface layer of V2O5. The dependence of the surface V=O species on calcination temperature was correlated with the flatness of the surface and the diffusion of lattice oxygen in near-surface layer.

Affiliations: 1: Department of Applied Chemistry, Graduate School of Engineering, Nagoya University, Furo-cho, Chikusa-ku, Nagoya 464, Japan; 2: Present address: Department of Industrial Engineering, Aichi Institute of Technology, Yagusa 470-03, Japan


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