Dual-Defective Two-Dimensional/Two-Dimensional Z-Scheme Heterojunctions for CO<sub>2</sub> Reduction
Shuwen Cheng, Zhehao Sun, Kang Hui Lim, Ary Anggara Wibowo, Tianxi Zhang, Tao Du, Liying Liu, Hieu T. Nguyen, Gang Kevin Li, Zongyou Yin, Sibudjing Kawi
Abstract
The target of photocatalytic CO 2 reduction is to achieve high selectivity, efficiency, and stability for a single chemical/fuel production. The construction of conventional Z-scheme heterojunctions is beneficial to improve the interfacial charge separation and redox capacities. However, the random dimensions of junction component(s) undermine the charge-to-surface transport for catalytic reactions, and the limited chemical structures of catalysts restrict surface activity/selectivity tailoring. In this work, we successfully overcome these issues by stacking/constructing an ultrathin dual-defective two-dimensional (2D)/2D Z-scheme heterojunction with growing functional anionic vacancies onto both reductive and oxidative components of the Z-scheme. The O-vacancy-rich BiOCl/N-vacancy-rich g-C 3 N 4 -based 2D Z-scheme exhibits excellent photoactivity in CO 2 reduction. The rate of CO 2 photoreduction to CO is around 45.33 μmol g –1 h –1, which is 11.7- and 12.2-fold those of untreated bulk g-C 3 N 4 and pristine BiOCl, respectively. Among them, N-vacancy-rich g-C 3 N 4 exhibits active and selective photoreduction ability, accompanied with oxidation reactions from O-vacancy-rich BiOCl. Such ultrathin defective Z-schemes not only retain their original features, i.e., enhanced charge separation and redox capacities, but also extend to lower energy photon absorption and ameliorate charge-to-surface transport in two redox components. Besides, density functional theory calculations unveiled the thermodynamically favored CO 2 -to-CO reduction path and energy barrier’s stepwise reduction at the COOH-to-CO rate-limiting step from defective g-C 3 N 4 to the single redox component defective junction and further to the defective junction with both redox components. This work provides an effective adaptable dual-defect engineering on 2D/2D heterojunctions to enhance CO 2 photoreduction.