Incorporating Nitrogen Atoms at TiO2 Lattice Sites for Improved Transparency and Visible-Light Photocatalytic Activity

Incorporating Nitrogen Atoms at TiO2 Lattice Sites for Improved Transparency and Visible-Light Photocatalytic Activity

Doping nitrogen into titanium dioxide (N–TiO2) is vital to extend its photocatalytic activity to the visible-light range. However, this often leads to a significant decrease in film transparency, which hinders its usage in environmental applications. In this study, we report the deposition of N–TiO2...

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Veröffentlicht in:Journal of physical chemistry. C 2023-08, Vol.127 (31), p.15271-15277
Hauptverfasser: Yang, Tong, Zhao, Yingzhi, Zuo, Yang, Chai, Jianwei, Chen, Zefeng, Wong, Lai Mun, Bao, Tian, Wang, Shijie, Jin, Yun Jiang, Yang, Ming
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C: Chemical and Catalytic Reactivity at Interfaces
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container_end_page 15277
container_issue 31
container_start_page 15271
container_title Journal of physical chemistry. C
container_volume 127
creator Yang, Tong
Zhao, Yingzhi
Zuo, Yang
Chai, Jianwei
Chen, Zefeng
Wong, Lai Mun
Bao, Tian
Wang, Shijie
Jin, Yun Jiang
Yang, Ming
description Doping nitrogen into titanium dioxide (N–TiO2) is vital to extend its photocatalytic activity to the visible-light range. However, this often leads to a significant decrease in film transparency, which hinders its usage in environmental applications. In this study, we report the deposition of N–TiO2 films with a visible-light activity and improved transparency. Using pulsed magnetron sputtering, we achieve a high concentration (∼7.5%) of nitrogen incorporation into anatase TiO2 films. This results in a much-reduced band gap (∼1.92 eV) and remarkable photocatalytic performance in the visible-light range. More importantly, the transparency of the films does not decrease significantly even at this high doping concentration, in contrast to the samples prepared using the conventional direct current (DC) sputtering process. First-principles calculations indicate that the improved incorporation of nitrogen at the substitutional lattice sites is responsible for the reduced band gap and improved transparency. This work demonstrates a viable method to achieve transparent N–TiO2 films with a visible-light activity, which could be useful for various environmental applications such as self-cleaning glass.
doi_str_mv 10.1021/acs.jpcc.3c03926
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title Incorporating Nitrogen Atoms at TiO2 Lattice Sites for Improved Transparency and Visible-Light Photocatalytic Activity
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