Abstract

Insufficient separation of photogenerated electron–hole and feeble CO2 activation remain the main obstacles in the access to high-performance CO2 reduction nowadays. Single-atom active sites engineering could be an efficient method through simultaneously promoting charge separation and CO2 activation. Herein, a model of Bi4O5I2 with single-atom Fe implanting and accompanying Bi decorating on surface is proposed to boost the performance. The single-atom Fe implantation decreases the value of surface work function, allowing the fast transition of photon-generated electrons from the surface of catalyst to CO2 molecule. In situ Fourier transform infrared (FT-IR) spectra, CO2 adsorption measurements, density functional theory (DFT) calculations, and efficient CO2 activation are realized on as-established single-atom catalyst. An exceptional yield of CO (23.77 μmol g–1 h–1) and CH4 production (4.98 μmol g–1 h–1) is acquired over optimized Bi4O5I2–Fe30 with 1.09 wt % of single-atom Fe, superior to Bi4O5I2, and most other reported photocatalysts. The work paves a insight into rational design of photocatalysts toward simultaneously facilitating carrier separation and CO2 activation from the angle of atom single metal.