Issue 14, 2019

Single metal atoms regulated flexibly by a 2D InSe substrate for CO2 reduction electrocatalysts

Abstract

The CO2 electroreduction reaction (CRR) is impeded by the low selectivity and high limiting potential of catalysts. Embedding single metal catalysts (SMCs) in a two-dimensional substrate is a promising strategy to address these issues. Herein, we design a novel type of SMC based on two-dimensional InSe and transition metal atoms (M@2DInSe) using density functional theory calculations. Different from the known SMCs on graphene, TiC, and TiN, the adsorption energies of *CO and *COOH intermediates on most of the M@2DInSe systems obey the linear relationship established on transition metals, with the results on few candidates deviating from the relationship significantly. Besides, the adsorption energy values of *CO/*COOH on M@2DInSe systems are closer to the values on Cu(111), compared to their bulk counterparts. These characters originate from the hybridization between InSe and d-/s-bands of metal atoms. These properties allow us to quickly screen the catalytic reactivity of M@2DInSe and thus can accelerate the selection of the optimal candidates for CO, HCOOH, H2, and CH4 production. Our results provide a reasonable material design scheme for further theoretical research and propose promising candidates with high activity and selectivity for experimental work.

Graphical abstract: Single metal atoms regulated flexibly by a 2D InSe substrate for CO2 reduction electrocatalysts

Supplementary files

Article information

Article type
Paper
Submitted
17 Jan 2019
Accepted
04 Mar 2019
First published
05 Mar 2019

J. Mater. Chem. A, 2019,7, 8210-8217

Single metal atoms regulated flexibly by a 2D InSe substrate for CO2 reduction electrocatalysts

C. Zhao, G. Zhang, W. Gao and Q. Jiang, J. Mater. Chem. A, 2019, 7, 8210 DOI: 10.1039/C9TA00627C

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