Facet-specific Active Surface Regulation of BixMOy (M=Mo, V, W) Nanosheets for Boosted Photocatalytic CO2 reduction

Photocatalytic performance can be optimized via introduction of reactive sites. However, it is practically difficult to engineer these on specific photocatalyst surfaces, because of limited understanding of atomic-level structure-activity. Here we report a facile sonication-assisted chemical reduction for specific facets regulation via oxygen deprivation on Bi-based photocatalysts. The modified Bi2MoO6 nanosheets exhibit 61.5 and 12.4 mu mol g(-1) for CO and CH4 production respectively, approximate to 3 times greater than for pristine catalyst, together with excellent stability/reproducibility of approximate to 20 h. By combining advanced characterizations and simulation, we confirm the reaction mechanism on surface-regulated photocatalysts, namely, induced defects on highly-active surface accelerate charge separation/transfer and lower the energy barrier for surface CO2 adsorption/activation/reduction. Promisingly, this method appears generalizable to a wider range of materials.

Automated summary

In this study, a facile sonication-assisted chemical reduction method was reported to optimize the photocatalytic performance of Bi-based photocatalysts via specific facets regulation through oxygen deprivation. The modified Bi2MoO6 nanosheets exhibited higher CO and CH4 production compared to the pristine catalyst, along with excellent stability and reproducibility.