生物炭与氧空位共修饰溴氧化铋光催化降解四环素

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Abstract A composite photocatalyst of bismuth oxybromide with oxygen vacancies covered by biochar (BC/OV-BiOBr, BOVB) was developed by hydrothermal method. Its photocatalytic performance was investigated with tetracycline (TC) as the target pollutant, and the catalytic effect was verified by dye pollutants. The results showed that 99.8% of tetracycline (TC) and 100% Rhodamine B(RhB) could be decomposed within 60min or 40min under visible light, of which degradation rates were 8.92 times and 9.82 times that of pure BiOBr, respectively. The degradation process of pollutants had strong resistance to pH change and low concentration co-existing ions. The results of phase characterization and photoelectrochemical performance test showed that the morphology was changed from flake to flower and the concentration of oxygen vacancies was increased after adding biochar, which were beneficial to improve the photoresponse and accelerate the charge transfer. Due to the synergistic effect between biochar and oxygen vacancies in driving the free radical chain reaction, the concentration of superoxide free radical (·O₂^-) in the system was increased, which was further transformed it into hydroxyl free radical (·OH), providing abundant strong oxidizing active species for pollutant degradation. In addition, good cyclic stability was certified by 5consecutive degradation experiments.

Key words： photocatalysis bismuth oxybromide biochar oxygen vacancies tetracycline free radical chain reaction

Received: 25 June 2024

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X52

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	Articles by authors
	YU Han-bo
	CHEN Ning-lu
	LI Ao-xiang
	HU Wei
	LI Ye-wang
	JI Xue-ting
	CHEN Ai-xin
	ZHAO Yu
	XIONG Ting

Cite this article:

YU Han-bo,CHEN Ning-lu,LI Ao-xiang等. Photocatalytic degradation of tetracycline by bismuth oxybromide co-modified with biochar and oxygen vacancies[J]. CHINA ENVIRONMENTAL SCIENCECE, 2025, 45(1): 310-321.

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http://www.zghjkx.com.cn/EN/ OR http://www.zghjkx.com.cn/EN/Y2025/V45/I1/310

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