BiOCl Nanoflowers with High Levels of Oxygen Vacancy for Photocatalytic CO<sub>2</sub> Reduction
Shuwen Cheng, Zhehao Sun, Kang Hui Lim, Tianxi Zhang, Emmerson Hondo, Tao Du, Liying Liu, Martyna Judd, Nicholas J. Cox, Zongyou Yin, Gang Kevin Li, Sibudjing Kawi
Abstract
CO 2 photoreduction products, such as CO and CH 4, have the potential to be further processed into valuable products and fuels, making this process a promising, environmentally friendly, and economically viable energy conversion technology. In this study, uniform BiOCl hierarchical nanoflowers with tunable thickness and abundant oxygen vacancies (OVs) were synthesized using a poly(vinylpyrrolidone)/ethylene glycol-assisted self-assembly method. The OV-rich BiOCl nanoflower (BiOCl-3) showed a 4-fold increase in photocatalytic conversion of CO 2 to CO compared to BiOCl nanosheets (BiOCl-1). Density functional theory (DFT) calculations and energy band analysis reveal anisotropy in the CO 2 reduction activity across different crystal facets, and the morphology can affect both the conduction band (CB) and band gap, resulting in a more negative CB edge for BiOCl compared to the reduction potential of CO 2 photoreduction to CO. This work provides a comprehensive analysis and explanation of the OV-rich BiOCl photocatalytic CO 2 reduction from both experimental and theoretical perspectives.