Oxygen Vacancy Engineering of Bi24O31Cl10 for Boosted Photocatalytic CO2 Conversion

Unearthing an ideal model to describe the role of defect sites for boosting photocatalytic CO2 reduction is rational and necessary, but it still remains a significant challenge. Herein, oxygen vacancies are introduced on the surface of Bi24O31Cl10 photocatalyst (Bi24O31Cl10‐OV) for fine‐tuning the p...

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Bibliographic Details
Published in:ChemSusChem 2019-06, Vol.12 (12), p.2740-2747
Main Authors: Jin, Xiaoli, Lv, Chade, Zhou, Xin, Ye, Liqun, Xie, Haiquan, Liu, Yue, Su, Huan, Zhang, Biao, Chen, Gang
Format: Article
Language:English
Subjects:
Bi24O31Cl10
Carbon dioxide
Carbon monoxide
Carrier density
Charge transfer
CO generation
CO2 reduction
Conduction bands
Current carriers
Oxygen
oxygen vacancies
Photocatalysis
Photocatalysts
Photochemistry
Solar energy conversion
Vacancies
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Summary:Unearthing an ideal model to describe the role of defect sites for boosting photocatalytic CO2 reduction is rational and necessary, but it still remains a significant challenge. Herein, oxygen vacancies are introduced on the surface of Bi24O31Cl10 photocatalyst (Bi24O31Cl10‐OV) for fine‐tuning the photocatalytic efficiency. The formation of oxygen vacancies leads to a new donor level near the conduction band minimum, which enables a faster charge transfer and higher carrier density. Moreover, oxygen vacancies can considerably reduce the energy for the formation of COOH* intermediates during CO2 conversion. As a result, the activity of Bi24O31Cl10‐OV for selective photoreduction of CO2 to CO is significantly improved, with a CO generation rate of 0.9 μmol h−1 g−1, which is nearly 4 times higher than that of pristine Bi24O31Cl10. This study reinforces our understanding of defect engineering in Bi‐based photocatalysts and underscores the potential importance of implanting oxygen vacancies as an effective strategy for solar energy conversion. Triple boost! The high abundance of oxygen vacancies in Bi24O31Cl10 play the following three roles for fully optimizing the CO2 conversion efficiency: (i) enhance charge density, (ii) improve separation of electron–hole pairs, and (iii) lower energy for the formation of intermediates during the process.
ISSN:1864-5631
1864-564X
DOI:10.1002/cssc.201900621