Theoretical investigation of platinum-like catalysts of molybdenum carbides for hydrogen evolution reaction

Developing high-active, stable and low-cost hydrogen evolution reaction (HER) catalysts is essential for industrial hydrogen production. Herein, a systematic study of the structures of molybdenum carbides and the related HER mechanism have been carried out based on density functional theory (DFT) calculations. The electronic properties and surface energies of three typical crystals of molybdenum carbides, i.e., alpha-MoC, beta-MoC and gamma-Mo2C, have been analyzed. It is shown that all the systems considered exhibit metallic behavior, among which the beta-MoC (110) plane is the most active facet with the largest surface energy (3.159 J.m(-2)). By comparing the Gibbs free energies, Delta G(H), we find that the (111) surface of beta-MoC has the smallest Delta G(H) of 0.089 eV, which is even superior than Pt-like catalysts, V8C7 (-0.114 eV), VC (- 0.191 eV) or MoO2 (0.15 eV).