TM<sub>2</sub>−B<sub>2</sub> Quadruple Active Sites Supported on a Defective C<sub>3</sub>N Monolayer as Catalyst for the Electrochemical CO<sub>2</sub> Reduction: A Theoretical Perspective
Yao Luo, Zengying Ma, Xueqian Xia, Junwen Zhong, Peng Wu, Yucheng Huang
Abstract
Abstract Developing high‐performance electrocatalysts for the CO 2 reduction reaction (CO 2 RR) holds great potential to mitigate the depletion of fossil feedstocks and abate the emission of CO 2 . In this contribution, using density functional theory calculations, we systematically investigated the CO 2 RR performance catalyzed by TM 2 −B 2 (TM=Sc, Ti, V, Cr, Mn, Fe, Co, Ni, Cu) supported on a defective C 3 N monolayer (V‐C 3 N). Through the screening in terms of stability of catalyst, activity towards CO 2 adsorption, and selectivity against hydrogen evolution reaction, Mn 2 −, Fe 2 −, Co 2 −, and Ni 2 −B 2 @V−C 3 N were demonstrated to be a highly promising CO 2 RR electrocatalyst. Due to quadruple active sites, these candidates can adsorb two or three CO 2 molecules. Strikingly, different products, distributing from C 1 to C 2+ , can be generated. The high activity originates from the synergistic effect of TM and B atoms, in which they serve as adsorption sites for the C‐ and O‐species, respectively. The high selectivity towards C 2+ products at the Fe 2 −, and Ni 2 −B 2 sites stems from moderate C adsorption strength but relatively weak O adsorption strength, in which a universal descriptor, that is, 0.6 Δ E C −0.4 Δ E O =−1.77 eV (Δ E C /Δ E O is the adsorption energy of C/O), was proposed. This work would offer a novel perspective for the design of high active electrocatalysts towards CO 2 RR and for the synthesis of C 2+ compounds.