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Highly Efficient Hydrosilylation of Ethyne over Pt/ZrO<sub>2</sub> Catalysts with Size-Dependent Metal–Support Interactions

Tengfei Zhang, Mingyan Li, Peng Zheng, Jing Li, Jiajian Gao, Hongyan He, Fangna Gu, Wenxing Chen, Yongjun Ji, Ziyi Zhong, Dingrong Bai, Guangwen Xu, Fabing Su

2022Industrial & Engineering Chemistry Research12 citationsDOI

Abstract

Replacing homogeneous noble-metal catalysts with supported catalysts in hydrosilylation reactions can overcome the difficulties of catalyst recovery and regeneration. Here, we report the scalable synthesis of heterogeneous Pt/ZrO2 catalysts with 1–5 wt % Pt supported on commercial ZrO2 nanocrystals. Pt/ZrO2 can effectively catalyze the hydrosilylation of triethoxysilane (TES) with ethyne to high-value triethoxyvinylsilane, even superior to the common homogeneous catalyst (H2PtCl6). Intensive characterizations indicate that the coating of ZrOx on Pt greatly depends on the size of Pt, with more ZrOx overlayers on smaller Pt metal particles. Among all the catalysts, 2Pt/ZrO2 exhibits the highest activity, optimal selectivity, and reusability toward hydrosilylation of TES with ethyne. The unusual catalytic properties of 2Pt/ZrO2 can be attributed to its more abundant surface PtOx species and the electron transfer between Pt and ZrO2. This change in local electronic properties promotes catalytic activity, which is also supported by the corresponding theoretical calculation. This work advances the understanding of metal–support interactions and provides a powerful approach to designing environmentally friendly heterogeneous catalysts for the industrially important hydrosilylation process.

Topics & Concepts

HydrosilylationCatalysisTriethoxysilaneChemical engineeringMetalMaterials scienceHeterogeneous catalysisChemistrySelectivityNanomaterial-based catalystHomogeneous catalysisOrganic chemistryEngineeringCatalytic Processes in Materials ScienceCovalent Organic Framework ApplicationsElectrocatalysts for Energy Conversion