High-index-faceted and electron density-optimized Ni3S2 in hierarchical NiWO4-Ni3S2@NiO/NF nanofibers for robust alkaline electrocatalytic hydrogen evolution br

Designing nonprecious electrocatalysts with outstanding performances in hydrogen evolution reaction (HER) via water splitting is attractive for renewable energy conversion. Here, a free-standing and binder-free electrode by in-situ growing a multi-level layered electrocatalyst consisted of NiWO4-coupled Ni3S2 nanofibers with secondary NiO layer on Ni foam (NiWO4-Ni3S2@NiO/NF) is devised, in which NiWO4 was recognized to boost the exposure of high-index {1 2 3} facets on Ni3S2 and NiO was identified to increase the electron density of Ni3S2 via accumulating S vacancies. Such an integration of high-index-facet exposure and electron-density optimization endowed the resultant NiWO4-Ni3S2@NiO/NF-3 (3 represents the nominal Ni: S molar ratio in fabricating Ni3S2) electrode with a more suitable H adsorption energy on the active Ni sites and a positive shift of the d-band center of Ni3S2 toward the Fermi level, resulting in a strengthened Ni-H interaction. As a consequence, a low over-potential of 89 mV to deliver a current density of 10 mA cm2 and a high turnover frequency of H2 generation of 1.5 x103 s1 for HER in 1 mol l1 KOH were acquired on NiWO4-Ni3S2@NiO/NF-3, both outperforming the Ni3S2/NF-1, NiWO4-Ni3S2/NF-1, and NiWO4-Ni3S2@NiO/NF-1 electrocatalysts. Remarkably, an electrolytic cell assembled by using NiWO4-Ni3S2@NiO/NF-3 as both anode and cathode delivered an overall-water-splitting current density of 10 mA cm2 at 1.64 V, evidencing its robust bifunctional catalytic ability in water splitting