ABSTRACT The kinetic bottleneck in solar‐driven hydrogen evolution lies in the slow proton and electron delivery, which severely limits the efficiency of proton‐coupled electron transfer (PCET). To address this, we report a bioinspired dual‐channel strategy using a CdIn 2 S 4 /Ni(OH) 2 (CIS/NOH) heterojunction. An S‐scheme charge‐transfer pathway is constructed to spatially separate strong reductants and oxidants, directing electrons to NOH for H 2 evolution and holes to CIS for benzyl alcohol oxidation. More critically, an interfacial hydrogen adsorption energy gradient drives directional proton migration from CIS to NOH, enriching protons precisely at the electron‐accumulation sites. This synergy of vectorial electron flow and proton migration co‐localizes reactants, dramatically accelerating the PCET process. The optimal catalyst achieves remarkable concurrent production of H 2 (17.96 mmol g –1 h –1 ) and benzaldehyde (12.63 mmol g –1 h –1 ). This work provides a novel blueprint for designing artificial photosynthetic systems by simultaneously managing charge and mass transport.
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