Abstract:

Single-atom catalysts (SACs) with metal atoms embedded in MXenes are potentially low-cost, highly efficient, and environment-friendly electrocatalysts for ammonia production due to their high stability, unique electronic structure, and the highest atom utilization. Here, density functional theory calculations are carried out to systematically investigate the geometries, stability, electronic properties of SACs with the 3d-transition metal M (Sc, Ti, V, Cr, Mn, Fe, Co, Ni, Cu, Zn) atoms embedded in the Ti defect sites of Ti₂CO₂ (denoted as M₁@Ti₂CO₂). A highly stable V₁@Ti₂CO₂ catalyst has been found to show excellent catalytic performance for N₂ reduction reaction to produce NH₃ after screening the 3d transition metals. The results show that V₁@Ti₂CO₂ can not only strongly adsorb N₂, but also exhibits an excellent Nitrogen reduction reaction (NRR) catalytic activity with a limiting potential of only −0.20 V and a high ability to suppress the competing hydrogen evolution reaction. The excellent NRR catalytic activity of V₁@Ti₂CO₂ is attributed to the strong covalent metal-support interaction that leads to superb N₂ adsorption ability of V atom. Furthermore, the embedded V single atoms facilitate electron transfer, thus improving the catalytic performance for NRR. These results demonstrate that V₁@Ti₂CO₂ is a potentially promising 2D material for building robust electrocatalyst for NRR.

Key words: Single-atom catalyst, Density functional theory, N₂ reduction, Defective Ti₂CO₂, Electrocatalysis