Interfacial anchoring cobalt species mediated advanced oxidation: Degradation performance and mechanism of organic pollutants
The biochar carrier was constructed based on pomelo peel biomass, and the surface crystallization, organic polymer protection and pyrolysis cascade strategies were used to effectively embed Co and CoO species in biochar to achieve efficient degradation of tetracycline organic. [Display omitted] The...
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Veröffentlicht in: | Journal of colloid and interface science 2025-02, Vol.679 (Pt B), p.67-78 |
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Format: | Artikel |
Sprache: | eng |
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Zusammenfassung: | The biochar carrier was constructed based on pomelo peel biomass, and the surface crystallization, organic polymer protection and pyrolysis cascade strategies were used to effectively embed Co and CoO species in biochar to achieve efficient degradation of tetracycline organic.
[Display omitted]
The development of highly catalytic activity, low-cost and environmentally friendly catalysts is crucial for the use of advanced oxidation processes (AOPs) to treat organic pollutants. In this study, to reduce costs, enhance catalytic activity and avoid secondary pollution form metal ions, pomelo peel was used as raw material, combined with surface crystallization, carbon layer protection and heat treatment technology to effectively construct AOPs catalyst that can efficiently activate peroxymonosulfate (PMS) to degrade harmful organic pollutants. Under the optimal conditions, the Co/BC-PMS system can degrade about 100 % of tetracycline (TC, a spectral antibiotic) within 5 min, and the degradation rate of TC can still reach 100 % even if Co/BC (cobalt anchored on biochar) was reused for 6 times. The Co/BC-PMS system can resist complex environmental conditions, including acidic solution, alkaline solution, coexisting ions, different water quality, and is universal for the degradation of most organic pollutants. The integrated purification column with Co/BC as the core realizes the continuous and complete degradation of organic pollutants and has the ability of practical application. Radical capture and monitoring combined with density-functional-theory calculations confirmed that the Co(111) and amorphous CoO sites in Co/BC are the key to driving PMS to degrade organic pollutants, Co/BC can efficiently adsorb PMS and promote the dissociation of PMS into highly active OH, SO4− and 1O2, and these reactive oxygen species jointly promote the degradation of organic pollutants. This study provides experimental support and theoretical insights for the design of efficient AOPs catalysts, and plays an important role in promoting the development of AOPs. |
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ISSN: | 0021-9797 1095-7103 1095-7103 |
DOI: | 10.1016/j.jcis.2024.10.097 |