1. Defect engineering-mediated Co9S8 with unexpected catalytic selectivity for heterogeneous Fenton-like reaction: Unveiling the generation route of 1O2 in VS active site.
- Author
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Fang, Zhimo, Qi, Juanjuan, Chen, Wenxing, Zhang, Lin, Wang, Jianhui, Tian, Caili, Dai, Qin, Liu, Wen, and Wang, Lidong
- Subjects
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REACTIVE oxygen species , *ELECTRONIC structure , *COMPLEX matrices , *POLLUTANTS , *DECONTAMINATION (From gases, chemicals, etc.) , *SULFUR - Abstract
Singlet oxygen (1O 2) plays a crucial role in Fenton-like reactions due to its high efficiency and selectivity in removing trace organic pollutants from complex water matrices. Defect engineering, which allows the efficient exposure of active sites and optimization of electronic structures, has rapidly emerged as a fundamental strategy for enhancing 1O 2 yield. Herein, we introduce tunable sulfur vacancy (V S) density into Co 9 S 8 catalysts for peroxymonosulfate (PMS) activation. The modulation of the octahedral Co (CoS 6) and tetrahedral Co (CoS 4) electronic structures by V S triggers the unexpected selective generation of 1O 2. The V S /PMS system exhibits excellent resistance to interference and highly selective degradation of electron-donating organic pollutants. Experimental and theoretical calculations revealed a new evolutionary route for 1O 2 involving two phases (Phase I: HSO 5 − → *O, Phase II: *O + HSO 5 − →*OO → 1O 2). This study provides a molecular-level understanding of V S -mediated catalytic selectivity for high-efficient decontamination applications. [Display omitted] • Co 9 S 8 catalysts with tunable V S was fabricated to PMS activation for contaminants degradation. • The optimized V S /PMS system achieved 1O 2 -dominated degradation mechanism. • Regulation d-band center of Co-3d orbital boosted the process of HSO 5 − adsorption and activation. • Combining experiment and DFT results revealed a new evolutionary route of 1O 2. [ABSTRACT FROM AUTHOR]
- Published
- 2023
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