The regulating effect of boron doping and its concentration on the photocatalytic overall water splitting of a polarized g-C3N5 material
Literature Information
Publication Date
2023-02-21
DOI
10.1039/D2CP05247D
Impact Factor
3.676
Authors
Xianghong Niu, Xuemei Zhang, Anqi Shi, Dazhong Sun, Dingbang Chen, Lu Zhang, Jialin Huang, Liqing Liu, Bing Wang, Xiuyun Zhang
View Original
Abstract
Photocatalytic overall water splitting with two-dimensional materials is a promising strategy to solve the problems of environmental pollution and energy shortage. However, conventional photocatalysts are often limited to a narrow visible photo-absorption range, low catalytic activity, and poor charge separation. Herein, given the intrinsic polarization facilitating the improvement of photogenerated carrier separation, we adopt a polarized g-C3N5 material combining the doping strategy to alleviate the abovementioned problems. Boron (B), as a Lewis acid, has a great chance to improve the capture and catalytic activity of water. By doping B into g-C3N5, the overpotential for the complicated four-electron process of the oxygen reduction reaction is only 0.50 V. Simultaneously, the B doping-induced impurity state effectively reduces the band gap and broadens the photo-absorption range. Moreover, with the increase of B doping concentration, the photo-absorption range and catalytic activity can be gradually improved. Whereas when the concentration exceeds 33.3%, the reduction potential of the conduction band edge will not meet the demand for hydrogen evolution. Therefore, excessive doping is not recommended in experiments. Our work affords not only a promising photocatalyst but also a practical design scheme by combining polarizing materials and the doping strategy for overall water splitting.
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Physical Chemistry Chemical Physics
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