Active Center Size-Dependent Fenton-Like Chemistry for Sustainable Water Decontamination

Accurately controlling catalytic activity and mechanism as well as identifying structure–activity–selectivity correlations in Fenton-like chemistry is essential for designing high-performance catalysts for sustainable water decontamination. Herein, active center size-dependent catalysts with single...

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Veröffentlicht in:	Environmental science & technology 2023-12, Vol.57 (50), p.21416-21427
Hauptverfasser:	Wu, Zelin, Xiong, Zhaokun, Liu, Wen, Liu, Rui, Feng, Xuezhen, Huang, Bingkun, Wang, Xinhao, Gao, Yixuan, Chen, Hong, Yao, Gang, Lai, Bo
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Sprache:	eng
Schlagworte:	Atomic clusters Catalysis Catalysts Catalytic activity Chemical activity Chemistry Cobalt Decontamination Density functional theory durability Hospital wastes hospitals Medical wastes Mineralization Nanoparticles Occurrence, Fate, and Transport of Aquatic and Terrestrial Contaminants Radicals Reaction mechanisms Reactive oxygen species Selectivity Size effects wastewater Wastewater treatment Water Water purification
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container_issue	50
container_start_page	21416
container_title	Environmental science & technology
container_volume	57
creator	Wu, Zelin Xiong, Zhaokun Liu, Wen Liu, Rui Feng, Xuezhen Huang, Bingkun Wang, Xinhao Gao, Yixuan Chen, Hong Yao, Gang Lai, Bo
description	Accurately controlling catalytic activity and mechanism as well as identifying structure–activity–selectivity correlations in Fenton-like chemistry is essential for designing high-performance catalysts for sustainable water decontamination. Herein, active center size-dependent catalysts with single cobalt atoms (CoSA), atomic clusters (CoAC), and nanoparticles (CoNP) were fabricated to realize the changeover of catalytic activity and mechanism in peroxymonosulfate (PMS)-based Fenton-like chemistry. Catalytic activity and durability vary with the change in metal active center sizes. Besides, reducing the metal size from nanoparticles to single atoms significantly modulates contributions of radical and nonradical mechanisms, thus achieving selective/nonselective degradation. Density functional theory calculations reveal evolutions in catalytic mechanisms of size-dependent catalytic systems over different Gibbs free energies for reactive oxygen species generation. Single-atom site contact with PMS is preferred to induce nonradical mechanisms, while PMS dissociates and generates radicals on clusters and nanoparticles. Differences originating from reaction mechanisms endow developed systems with size-dependent selectivity and mineralization for treating actual hospital wastewater in column reactors. This work brings an in-depth understanding of metal size effects in Fenton-like chemistry and guides the design of intelligent catalysts to fulfill the demand of specific scenes for water purification.
doi_str_mv	10.1021/acs.est.3c06887
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Differences originating from reaction mechanisms endow developed systems with size-dependent selectivity and mineralization for treating actual hospital wastewater in column reactors. 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Sci. Technol</addtitle><description>Accurately controlling catalytic activity and mechanism as well as identifying structure–activity–selectivity correlations in Fenton-like chemistry is essential for designing high-performance catalysts for sustainable water decontamination. Herein, active center size-dependent catalysts with single cobalt atoms (CoSA), atomic clusters (CoAC), and nanoparticles (CoNP) were fabricated to realize the changeover of catalytic activity and mechanism in peroxymonosulfate (PMS)-based Fenton-like chemistry. Catalytic activity and durability vary with the change in metal active center sizes. Besides, reducing the metal size from nanoparticles to single atoms significantly modulates contributions of radical and nonradical mechanisms, thus achieving selective/nonselective degradation. Density functional theory calculations reveal evolutions in catalytic mechanisms of size-dependent catalytic systems over different Gibbs free energies for reactive oxygen species generation. Single-atom site contact with PMS is preferred to induce nonradical mechanisms, while PMS dissociates and generates radicals on clusters and nanoparticles. Differences originating from reaction mechanisms endow developed systems with size-dependent selectivity and mineralization for treating actual hospital wastewater in column reactors. 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subjects	Atomic clusters Catalysis Catalysts Catalytic activity Chemical activity Chemistry Cobalt Decontamination Density functional theory durability Hospital wastes hospitals Medical wastes Mineralization Nanoparticles Occurrence, Fate, and Transport of Aquatic and Terrestrial Contaminants Radicals Reaction mechanisms Reactive oxygen species Selectivity Size effects wastewater Wastewater treatment Water Water purification
title	Active Center Size-Dependent Fenton-Like Chemistry for Sustainable Water Decontamination
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