Abstract Photocatalytic CO 2 reduction using semiconductor quantum dots (QDs) holds great promise for solar‐to‐fuel conversion, yet challenges in selectivity and efficiency remain barriers to applications. Herein, a Mg 2+ ‐doped CdS (Mg:CdS) QDs is presented that enables highly selective CH 4 production via a dual‐site catalytic mechanism. Experimental and theoretical investigations reveal that Mg 2+ doping induces profound electronic and structural modifications in CdS QDs. Notably, Mg 2+ doping introduces distinct Lewis acid–base dual sites on the QD surface, effectively promoting CO 2 adsorption and activation through a Cd⋯C═O⋯Mg interaction. This unique activation pathway, elucidated via in situ infrared spectroscopy and density functional theory calculations, facilitates the formation of *CHO intermediates by reducing the O─C─O bond angle and weakening C═O bonds, thereby steering the reaction selectivity toward CH 4 . As a result, the Mg:CdS QDs achieve an exceptional CH 4 selectivity of 88.7% with a production rate of 45.8 µmol g −1 h −1 under simulated solar irradiation, significantly surpassing undoped CdS. This study not only unveils a novel mechanistic paradigm for alkaline earth metal doping in CO 2 photoreduction but also provides a strategy for engineering highly selective QD photocatalysts for solar‐driven CO 2 conversion.
Liu et al. (Tue,) studied this question.