Significantly Enhanced Photocatalytic CO2 Reduction by Surface Amorphization of Cocatalysts

Abstract Rational phase engineering of reduction cocatalyst offers a promising route to modulate the photocatalytic activity and selectivity in the conversion of CO 2 to chemical feedstocks. However, it remains a great challenge to choose a suitable phase given that high‐crystallinity phase is more conducive to the charge transfer and separation, while amorphous phase is more favorable for the adsorption and activation of CO 2 molecules. To resolve this dilemma, herein, with Pd as a well‐defined model, a surface amorphization strategy has been developed to fabricate crystalline@amorphous semi‐core‐shell cocatalysts based on the transformation of outer layer atoms of crystalline cocatalysts to disorder phase. According to the theoretical and experimental analysis, in the heterostructured cocatalysts, crystalline core shuttles the photoexcited electrons from light‐harvesting semiconductor to amorphous shell due to its strong electronic coupling with both components. Meanwhile, amorphous shell provides efficient active sites for preferential activation and conversion of CO 2 and suppression of undesirable proton reduction. Benefiting from the synergistic effects between crystalline core and amorphous shell, the optimized heterophase cocatalyst with suitable thickness of amorphous shell achieves superior CO (22.2 µmol g cat −1 h −1 ) and CH 4 (38.1 µmol g cat −1 h −1 ) formation rates with considerable selectivity and high stability in comparison with crystalline and amorphous counterparts.