S‐Vacancy‐Induced "Proton Fence Effect" Enables Selectivity Switching Between CH4 and CO in Photo‐Assisted CO2 Electroreduction

Upcycling CO ₂ into high‐value C ₁ products is impressive for achieving carbon neutrality and energy sustainability, while rational modulation of C ₁ product selectivity is one of the biggest challenges in electrocatalytic CO ₂ reduction reaction (eCO ₂ RR) due to the competing reaction pathways and thermodynamic limitation. Here, we showcase a “proton fence” strategy enabled by in situ adsorbed *OH on sulfur vacancies (S _V ) to ultraselectively switch the C ₁ product between CH ₄ and CO during CO ₂ RR, with Faraday efficiency of 93.6% and 95.3%, respectively. In situ measurements uncover that the photo‐generated holes counteract Cu ²⁺ electroreduction to retain the intact structure of CuInS ₂ /CuS, while *OH dissociated from water can spontaneously anchor toward S _V to hinder the local proton migration, completely circumventing multiproton products. Meanwhile, the preferential desorption of *CO from Cu centers adjacent to the *OH‐anchored S _V renders the exclusive formation of CO. In the absence of S _V , *CO can be further hydrogenated in a lower free energy/even spontaneously to afford CH ₄ . The proposed proton confinement effect furnishes a promising reference for the selectivity control of eCO ₂ RR, and the photo‐assisted electroreductive protocol demonstrates a paradigm of in situ stabilization of electron‐intolerant catalytic structures.