Efficient defect engineering and in-situ carbon doping in ultra-fine TiO2 with enhanced visible-light-response photocatalytic performance

The wide bandgap and low photocatalytic efficiency are acknowledged as the main problems of the photocatalytic activities of TiO2. Herein, an effective strategy combing defect engineering and heteroatom doping is developed to expand the region covering visible light response and construct the active...

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Bibliographic Details
Published in:Journal of alloys and compounds 2022-04, Vol.901, p.163490, Article 163490
Main Authors: Ning, Jing, Mu, Chunhong, Guo, Xinpeng, Yang, Ruiquan, Jonathan, Ruhumuriza, Jiao, Wei, Wu, Xiaoping, Jian, Xian
Format: Article
Language:English
Subjects:
Anatase
Carbon
Carbon doping
Catalytic activity
Core-shell structure
Doping
Energy gap
Lattice vacancies
Oxygen vacancy
Photocatalysis
Photodegradation
PICD
TiO2
Titanium dioxide
Vacancies
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Summary:The wide bandgap and low photocatalytic efficiency are acknowledged as the main problems of the photocatalytic activities of TiO2. Herein, an effective strategy combing defect engineering and heteroatom doping is developed to expand the region covering visible light response and construct the active surface. A plasma-induced carbon doping (PICD) method is adopted to achieve a binary core-shell structure containing outer defect-layer shell of oxygen vacancy and inside crystalline anatase TiO2 core (~ 5 nm). The outstanding photocatalytic activity for visible-light-driven degradation of RhB and MO originates from narrowed bandgap (~ 2.30 eV) and improved photo-induced charge separation. Moreover, the excellent stability towards RhB degradation (100%) after 4 recycles exhibits the great potential applicability. RhB removal efficiency could reach to 100% even in the wide pH range from 3 to 11. Furthermore, the synergy effect by outside oxygen-vacancies layer and interstitial carbon doping enhanced the photoelectrochemical (PEC) performances significantly. This PICD technology can induce carbon doping and defect layer with active cites, which opens up a new way to design novel visible-light-responsive photocatalysis. [Display omitted] •A plasma-induced strategy combines in-situ carbon doping and defect engineering.•Wide UV–vis response range is from 200 nm to 800 nm.•A strong absorption and degradation under visible light irradiation of MO for OV-TiO2@C.•The mechanism of photodegradation RhB is investigated by In-situ DRIFTS measurement.•The improved PEC performances benefits from the synergy effect by continuous oxygen-vacancies layer and interstitial carbon doping.
ISSN:0925-8388
1873-4669
DOI:10.1016/j.jallcom.2021.163490