Electrochemical water splitting is an efficient and ecofriendly method for hydrogen production. Although Pt-based catalysts are the most widely used for the hydrogen evolution reaction (HER), their scarcity and high cost limit their applications. Therefore, the development of highly active catalysts based on nonprecious metals is required. In this study, a Mo-doped NiSe catalyst was synthesized on Ni foam (NF) as the Ni source via hydrothermal. The catalyst exhibited a two-dimensional nanoflower structure, and the presence of crystalline NiSe and Ni 3 Se 2 was confirmed. Mo-doped NiSe achieved a current density of −10 mA cm −2 at an overpotential of −148 mV in 1 M KOH, showing superior HER activity to that of NiSe (−194 mV), p -MoSe 2 (−314 mV), and NF (−249 mV). Mo doping enhanced the activity by increasing the electrochemically active surface area and tuning the d-band of Ni. Long term stability tests over 6000 potential cycles reveal that the catalyst undergoes surface reconstruction while preserving its crystalline framework during this process. Mo is partially leached and readsorbed as high valent Mo 6+ , whereas Ni and Se remain largely unchanged. These results demonstrated that Mo-doped NiSe is a promising alkaline HER catalyst with excellent stability. • Mo doped NiSe was grown on NF by hydrothermal synthesis. • Mo doping increases the specific surface area and enhances HER activity. • Mo-doped NiSe needs only −148 mV at −10 mA cm −2 and exhibited excellent stability. • Potential cycling forms an amorphous Mo oxidation state and reconstructs the surface. • Electronic reconstruction preserves high HER catalytic activity in alkaline media.
Shin et al. (Wed,) studied this question.