Vacancies in catalysts are known to critically influence catalytic activity, yet metal vacancies-especially non-interfacial metal vacancies-remain underexplored due to their intrinsically high formation energies and synthetic challenges. In this work,… Click to show full abstract
Vacancies in catalysts are known to critically influence catalytic activity, yet metal vacancies-especially non-interfacial metal vacancies-remain underexplored due to their intrinsically high formation energies and synthetic challenges. In this work, we successfully prepared a Ni2.8S2 precursor containing nickel vacancies through a high-temperature solid-state reaction, which was subsequently transformed in situ into a NiS/NiSe2 heterostructure featuring dual non-interfacial metal vacancies. Notably, these vacancy characteristics were preserved during the phase transition, yielding a robust NiS/NiSe2 heterointerface with enhanced charge transfer and strengthened interphase coupling. Compared with a vacancy-free NiS/NiSe2 counterpart, the vacancy-enriched heterostructure exhibits markedly improved hydrogen evolution activity. Density functional theory (DFT) calculations further reveal that the dual non-interfacial vacancies induce a downward shift in the Ni d-band center, which plays a pivotal role in boosting catalytic performance. This study underscores the importance of non-interfacial metal vacancies in designing high-performance electrocatalysts for hydrogen evolution and offers valuable insights for developing efficient, low-cost, and non-precious metal-based catalysts.
               
Click one of the above tabs to view related content.