Synergistic effects of heteroatom-decorated MXene catalysts for CO reduction reactions

In this study, using the density functional theory calculations, we present a strategy to improve the activity and selectivity of electrocatalytic CO reduction reactions (CORRs) towards CH 4 production occurring on single transition metal (TM) atoms embedded in a defective MXene Mo 2− x TiC 2 O y wi...

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Bibliographic Details
Published in:Nanoscale 2020-08, Vol.12 (29), p.1588-15887
Main Authors: Li, Lei, Li, Baihai, Guo, Haoran, Li, Yanle, Sun, Chenghua, Tian, Ziqi, Chen, Liang
Format: Article
Language:English
Subjects:
Carbon monoxide
Catalytic activity
Chemical reduction
Density functional theory
Electrocatalysts
Free energy
Hydrogen evolution reactions
Methane
MXenes
Oxygen atoms
Selectivity
Steric hindrance
Transition metals
Triangles
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Summary:In this study, using the density functional theory calculations, we present a strategy to improve the activity and selectivity of electrocatalytic CO reduction reactions (CORRs) towards CH 4 production occurring on single transition metal (TM) atoms embedded in a defective MXene Mo 2− x TiC 2 O y with one oxygen vacancy. Owing to the unique geometric and electronic structures, the exposed TM-Mo-Mo triangle can serve as an active site, and the surrounding oxygen atoms can break the scaling relationships between the CORR intermediates via the steric hindrance. The synergistic effects result in an excellent catalytic performance for CORRs. Based on the extensive investigation of series of candidates, W-decorated MXene was identified as the most promising CORR electrocatalyst, with a high selective activity towards the CH 4 production and strong suppression of competing hydrogen evolution reactions (HERs). The adsorption free energy of *COH [Δ G ads (*COH)] is proposed as a descriptor to establish a relationship with the catalytic activity. Our rational design principles and rapid screening methods may shed light on the development of other highly efficient CORR electrocatalysts, as well as the other electrochemical systems. The as-designed heteroatom catalysts with steric hindrance efficiently improve the activity and selectivity of CO reduction into CH 4 .
ISSN:2040-3364
2040-3372
DOI:10.1039/d0nr03632c