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Ultrahigh Selective Hydrogenation of Furfural Enabled by Modularizing Hydrogen Dissociation and Substrate Activation

Shuai Wang, Yipin Lv, Jianyu Ren, Xu Zhou, Qiuping Yang, Huaiqing Zhao, Daowei Gao, Guozhu Chen

2023ACS Catalysis40 citationsDOI

Abstract

Designing optimal heterogeneous metal hydrogenation catalysts for biomass conversion with simultaneously high activity and selectivity is a significant but challenging topic. Herein, we report a modularized hydrogenation mode with hydrogen dissociation and substrate activation on different sites (e.g., Pt and Cu), where Pt nanoclusters are responsible for H 2 dissociation and Cu nanoparticles act as the active center for further substrate activation. Specifically, TS-1 zeolite@mesoporous silica with a core–shell structure was fabricated, in which the Pt and Cu species are confined within micropores and mesopores, respectively. Such configurations allow facile dissociation of H 2 on Pt sites, followed by the migration of spilled-over hydrogen atoms to the Cu sites where the adsorbed substrates are activated for catalytic hydrogenation. This synergy yields an efficient furfural hydrogenation system with a high turnover frequency (32.8 h –1 ) and a remarkable furfuryl alcohol selectivity (>99.6%). The modularizing strategy opens up an innovative pathway for fabrication of hydrogenation catalysts with outstanding activity and high selectivity.

Topics & Concepts

SelectivityCatalysisNanoclustersFurfuryl alcoholFurfuralDissociation (chemistry)Mesoporous materialChemistryChemical engineeringMaterials scienceAdsorptionOrganic chemistryEngineeringCatalysis for Biomass ConversionCatalysis and Hydrodesulfurization StudiesNanomaterials for catalytic reactions
Ultrahigh Selective Hydrogenation of Furfural Enabled by Modularizing Hydrogen Dissociation and Substrate Activation | Litcius