Dual-function oxygen vacancy of BiOBr intensifies pollutant adsorption and molecular oxygen activation to remove tetracycline hydrochloride

[Display omitted] •BiOBr nanospheres with oxygen vacancy is prepared via solvothermal method.•BiOBr-OV exhibits better TC removal performance by adsorption and degradation.•Oxygen vacancy enhances ion exchange adsorption due to the effective hydrolysis and dehydration.•Surface complex via adsorption...

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Bibliographic Details
Published in:Chemical engineering journal (Lausanne, Switzerland : 1996) Switzerland : 1996), 2023-01, Vol.451, p.138731, Article 138731
Main Authors: Zhang, Wenhai, Bian, Zhaoyong, Peng, Yiyin, Tang, Hanyu, Wang, Hui
Format: Article
Language:English
Subjects:
Adsorption
BiOBr
Molecular oxygen activation
Oxygen vacancy
Surface complex
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Summary:[Display omitted] •BiOBr nanospheres with oxygen vacancy is prepared via solvothermal method.•BiOBr-OV exhibits better TC removal performance by adsorption and degradation.•Oxygen vacancy enhances ion exchange adsorption due to the effective hydrolysis and dehydration.•Surface complex via adsorption promotes degradation by faster charge transfer.•Oxygen vacancy achieves an effective activation of molecular oxygen. Oxygen vacancy is an important factor for pollutant adsorption and molecular oxygen activation. How to construct the dual-function oxygen vacancy is still a challenge for environmental remediation. Here, BiOBr (3D-self-assembled nanospheres) with different contents of oxygen vacancies was prepared via solvothermal method and calcination, which intensified antibiotic adsorption and molecular oxygen activation to remove tetracycline hydrochloride. Adsorption experiments and theoretical calculations revealed that oxygen vacancies enhanced the adsorption of pollutants via ion exchange. Furthermore, surface complexation due to adsorption facilitated degradation through faster charge transfer, which was proven by photoelectrochemical tests and TRPL spectroscopy. Quenching experiments, EPR and photoelectrochemical measurement indicated that oxygen vacancies facilitated charge transfer, to increase the activation of molecular oxygen and subsequent ∙O2- and 1O2 production for pollutant degradation. This study provides an in-depth explanation of the role of oxygen vacancies in tetracycline adsorption, surface complex due to the intermediate state in adsorption and molecular oxygen activation, as well as a reference for antibiotic removal via adsorption coupling degradation.
ISSN:1385-8947
1873-3212
DOI:10.1016/j.cej.2022.138731