A Novel Bimetallic NiMo Carbide Nanowire Array for Efficient Hydrogen Evolution.

Design and fabrication of noble metal-free hydrogen evolution electrocatalysts with high activity is significant to future renewable energy systems. In this work, self-supported NiMo carbide nanowires have been developed on carbon cloth (Ni3Mo3C@NPC NWs/CC; NPC is N,P-doped carbon) through an electropolymerization-assisted procedure. During the synthesis process, NiMoO4 nanowires were first grown on CC through a hydrothermal reaction which is free of any polymer binder like Nafion. The as-prepared NiMoO4 NWs/CC was then coated by a layer of polypyrole (PPy) by electropolymerization that serves as carbon source for the subsequent conversion to Ni3Mo3C@NPC NWs/CC by carbothermal reduction. The experimental results indicate that the judicious choices of the amount of coated PPy and the pyrolysis temperature are essential for obtaining pure phase and nanowire array structure of Ni3Mo3C@NPC NWs/CC. Benefitting from the pure phase of bimetallic carbide, the unique architecture of nanowire array and the self-supported merit, the optimized Ni3Mo3C@NPC NWs/CC electrode exhibits excellent HER performance in both acidic and alkaline media. It requires low overpotentials of 161 mV and 215 mV to afford a high current density of 100 mA cm-2 toward the HER in acidic and alkaline media, respectively, and the catalytic activity is maintained for at least 48 h, which makes it among the best HER electrocatalysts based on metallic carbides yet reported.