催化作用
铂金
氧化还原
金属
化学
离子键合
氧化态
反应速率
氧气
无机化学
有机化学
离子
作者
Mingzhi Wang,Yige Zhang,Zhuangzhuang Wu,Yanping Zheng,Zhaohui Zhou,Weizheng Weng
标识
DOI:10.1016/j.cej.2022.138171
摘要
• Pt/CeO 2 catalysts dominated with either PtO x and Pt–O–Ce species were prepared. • Pt–O–Ce species remain in the ionic state during the reaction, while PtO x species can be reduced to metallic Pt 0 . • Metallic Pt NPs generated by H 2 reduction can get reoxidized to inactive Pt n+ –O–Ce (n=2–δ). • The oxidation of metallic Pt NPs arises from oxygen reverse spillover from the CeO 2 support. • Pt NPs obtained by CO reduction are not prone to oxidation during the reaction. Ceria supported platinum catalysts play an important role in exhaust emission catalysis. Because of the interactions between catalyst and reactants under complex reaction conditions, Pt species may exhibit dynamic structural changes as a function of the reactant pressure and reaction temperature, making it difficult to determine the structure-performance relationship. In this study, the chemical states and dynamics of several typical Pt species, including PtO x , Pt–O–Ce and reduced Pt nanoparticles (NPs), in CO oxidation reaction and their correlations with activity were explored. It was found that Pt–O–Ce species with strong Pt–O bonds remained in the ionic state during the light off reaction, while PtO x species that interacted weakly with CeO 2 could be easily reduced to metallic Pt (Pt 0 ), which also exhibited better activity due to the enhanced reducibility of the Pt NPs-CeO 2 interface. Although the initial activity of the Pt/CeO 2 catalyst can be improved through reduction with H 2 , the metallic Pt NPs, especially derived from the reduction of Pt–O–Ce dominated catalysts, can get reoxidized to the less active Pt n+ –O–Ce (n = 2–δ) species during the reaction. A detailed in situ characterization revealed that the oxidation of metallic Pt NPs arises from oxygen reverse spillover from the CeO 2 support. This study shows that understanding the reaction-driven structural dynamics of Pt species is essential for exploring the reaction mechanism and elucidating how the catalyst is activated and deactivated in the reaction.
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