Charging d-Orbital Electron of ReS2+x Cocatalyst Enables Splendid Alkaline Photocatalytic H2 Evolution

Rhenium disulfide (ReS₂) holds expansive perspective in photocatalytic water-splitting field, but its H₂-production rate is severely impeded by the strong hydroxyl (OH_ad) adsorption on catalytic Re atoms. Herein, an ingenious strategy about charging d-orbital electrons of ReS_2+x cocatalyst by integrating metallic Au is explicitly clarified to effectively accelerate OH_ad desorption for promoting alkaline photocatalytic H₂-evolution activity. To this end, core-shell Au@ReS_2+x nanostructures as H₂-production cocatalysts are skillfully fabricated onto TiO₂ by a directional assembly pathway. Experimental and theoretical data validate an free-electron transfer from metallic Au core to S-rich ReS_2+x shell, thus essentially charging electrons to the d-orbital of Re atoms to construct active Re^(4-δ)+ sites. The charged d-orbital electron state of Re^(4-δ)+ atoms raises antibonding occupancy of the Re^(4-δ)+? OH_ad bonds, thereby accelerating OH_ad desorption and endowing core-shell Au@ReS_2+x cocatalysts an efficient H₂ production from alkaline water splitting. Moreover, the core-shell Au@ReS_2+x cocatalysts can effectively capture photogenerated electrons from TiO₂ as unveiled by operando Kelvin probe force microscopy. Consequently, the optimized TiO₂/Au@ReS_2+x photocatalyst achieves an exceptional H₂-production rate of 6013.45 µmol h^?1 g^?1 with releasing visual H₂ bubbles in alkaline media. This research furnishes original insights for charging orbital electrons to optimize the adsorption strength between intermediates and catalytic atoms.