Surface Dual Metal Occupations in Fe-Doped FeBiO Induce Highly Efficient Photocatalytic CO Reduction.

CO possesses extraordinary thermodynamic stability, and its reduction reaction involves multiple electron-transfer processes. Thus, high-density electron occupation on a catalyst surface is an effective driving force for improving the photocatalytic activity. Here, we report on the fabrication of Fe-doped BiO catalysts (denoted as FeBiO) with different Fe contents using the solvothermal method. The self-assembled catalyst has a nanoflower-like morphology, and its performance of CO reduction to CO is improved largely dependent on the Fe content. In the sample with a 7.0% Fe content (FeBiO), the CO evolution rate reaches 30.06 μmol g h, which is about 6 times higher than the 4.95 μmol g h of pristine BiO, and shows excellent photostability after three cycles, with each cycle lasting for 7 h. Theoretical calculation and spectral characterization reveal that such a good CO reduction reaction performance arises from effective surface occupation of Fe, which not only enhances sunlight absorption but also significantly increases the surface electron density on the double metal active sites. This work provides a new strategy for improving the photocatalytic performance by surface metal doping in some metal oxide photocatalysts.