Abstract
In-situ surface self-reconstruction of electrocatalysts plays a crucial role in efficiently catalyzing the hydrogen evolution reaction (HER) and the organic compound oxidation reaction. Herein, a core@shell structure of metallic Ni@O-riched Ni layer (Ni@O-Ni) pre-electrocatalyst was established, which possesses a unique self -adaptable ability for the potential-dependent reconstruction to generate actual active sites for catalytic re-actions. The reconstructed Ni@Ni/NiOx during the cathodic activation process shows an outstanding HER ac-tivity with a low overpotential of 71 mV to reach 10 mA cm(-2) and remarkable stability in 1.0 M KOH. In addition, the core@shell structured Ni@NiOx during the anodic activation process contributes to abundant redox reactions for the electro-oxidation of organic compound. Especially, the Ni@NiOx exhibits an ultralow potential of 1.309 V at 10 mA cm(-2) and similar to 99 % yield of benzoic acid (Ph-COOH) product for the electro-oxidation of benzyl alcohol (Ph-CH2OH). In-situ Raman spectra corroborate the reversible transformation of Ni2+-O-x and gamma-Ni3+-OOH and reveal the vital role of gamma-Ni3+-OOH in seizing the proton for Ph-CH2OH electro-oxidation re-action. Moreover, the constructed integrated water splitting coupled with Ph-CH2OH electro-oxidation needs only a cell voltage of 1.438 V at 10 mA cm(-2), resulting in an electrical energy saving of 14.3 % compared to overall water splitting. This work proposes profound insights into the correlation between surface features, potential-dependent reconstruction, and the multifunctionality of electrocatalysts.