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Optimizing Selectivity in VO<sub><i>x</i></sub>/TiO<sub>2</sub> Catalysts for Ammoxidation: Insights from Structure–Performance Relationships

Hang Yu, Shanjun Mao, Bing Lu, Hao Wang, Xie Zhang, Menghui Qi, Ruiliang Gao, Yong Wang

2024ACS Catalysis17 citationsDOI

Abstract

Multicomponent reactions such as ammoxidation are highly desirable for chemical synthesis. The complicated reaction network and catalytic active sites involved, however, make it rather challenging for extensive structure–performance relationship investigations and subsequent rational design of an efficient catalyst. In this work, efficient VO x /TiO 2 catalysts with concise components and exquisite structure design demonstrated 95% selectivity at 98% conversion under 2070 h –1 for 3-picoline ammoxidation. After clarifying that the oxidative dehydrogenation process is rate-limiting, we assumed that the abundance of reactive surface lattice oxygen at the interface of vanadium–titanium is the key to high productivity and suppression of oxidation side reactions since low reaction temperature is beneficial for enlarging the difference in rates of different energy barriers. In addition, rather than applying the traditional neutralization method with alkaline components, in situ formed V 2 O 5 crystallite was subtly to cover the strong acid sites on VO x /TiO 2 catalysts in that the strong adsorption of pyridine nitrogen in 3-cyanopyridine on strong acid sites can lead to severe hydrolysis side reactions.

Topics & Concepts

AmmoxidationCatalysisDehydrogenationSelectivityInorganic chemistryChemistryVanadiumAdsorptionPyridineAcrylonitrilePhysical chemistryOrganic chemistryCopolymerPolymerCatalysis and Oxidation ReactionsCatalytic Processes in Materials SciencePolyoxometalates: Synthesis and Applications
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