A First-Principles Screening for Axial Ligand Regulation of Electrocatalytic Carbon Dioxide Reduction on Dual-Metal Atomic Catalysts (MMN‑R).

A primary challenge in the carbon dioxide reduction reaction (CORR) is the rational design and engineering of high-efficiency electrocatalysts. A series of MMN catalysts (MM = NiNi, CoNi, CoFe, CoCo) with precisely tailored axial ligands (R = -OH, -COH, -CN) have been high-throughput screened out to exhibit optimal electrocatalytic activity, which is extended to further estimate their CORR performance in this work. The adsorption energies of three distinct ligands at the M-M bridge site are evaluated to quantitatively assess the ligand stabilization. On pristine and ligand-engineered MMN catalysts, the free energy variation along CORR pathways leading to C1 products reveals that the initial proton-coupled electron transfer to form the *HCOO/COOH intermediate is the main potential-limiting step of yielding the key intermediate CO. The formation barrier energy difference of <0.06 eV between *HCOO and *COOH intermediates on pristine CoCo/CoFe/CoNi and CN-functionalized CoFe/CoCo catalysts facilitates *CO intermediate generation and enables the subsequent *CO-*CO coupling to C2 products for formation of CHOH and CH. However, -COH and -OH modification excludes *CO-intermediate formation and directs the reaction toward CH and CHOH production due to the large kinetic energy difference of 0.96-1.11 eV between *HCOO and *COOH. Our results provide a possible axial ligand engineering strategy of regulating C1/C2 product selectivity on different dual-atom catalysts.