Strong Metal‐Support Interactions: From Characterization, Manipulation to Application in Fischer‐Tropsch Synthesis and Atmospheric CO2 hydrogenation

Strong metal‐support interactions (SMSI) featuring the formation of encapsulation overlayer around metal nanoparticles has drawn much attention in heterogeneous catalysis. Recent years, various novel SMSI phenomena have been observed and the nature of SMSI also has been revealed with the improvement...

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Bibliographic Details
Published in:ChemCatChem 2024-08, Vol.16 (15), p.n/a
Main Authors: Zhang, Wenzhe, Lin, Heyun, An, Yunlei, Lin, Tiejun, Zhong, Liangshu
Format: Article
Language:English
Subjects:
Carbon dioxide
Catalysis
Chemical activity
Chemical reactions
Chemical synthesis
COx hydrogenation
Encapsulation
Heterogeneous catalysis
Hydrogenation
Metal support interaction
Methanation
Shift reaction
Structural analysis
Structural sensitivity
Water gas
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Summary:Strong metal‐support interactions (SMSI) featuring the formation of encapsulation overlayer around metal nanoparticles has drawn much attention in heterogeneous catalysis. Recent years, various novel SMSI phenomena have been observed and the nature of SMSI also has been revealed with the improvement of characterization techniques. Understanding the SMSI effect could deepen the insight into the structure‐activity relationship of metal‐supported catalysts, and rationally guide the design of special metal‐interface sites to manipulate catalytic behavior in chemical reaction. In this review, the research progress of SMSI and its application in heterogeneous COx hydrogenation are briefly surveyed, with emphasis on the advanced characterization, manipulation strategy and specific role of SMSI in Fischer‐Tropsch synthesis process, CO2 methanation and Reverse Water Gas Shift reaction. The current challenges and perspectives for the development of SMSI are also discussed. Strong metal‐support interaction (SMSI) has emerged as an efficient strategy to design metal‐support interfacial catalysts and manipulate catalytic behavior of a specific chemical reaction. This review mainly focuses on the latest discoveries of SMSI in terms of advanced characterization, manipulation strategy and the catalytic behavior in Fischer‐Tropsch Synthesis and atmospheric CO2 hydrogenation. The current challenges and future developments of SMSI is also outlooked.
ISSN:1867-3880
1867-3899
DOI:10.1002/cctc.202301623