Facilely Tuning the First-Shell Coordination Microenvironment in Iron Single-Atom for Fenton-like Chemistry toward Highly Efficient Wastewater Purification

Facilely Tuning the First-Shell Coordination Microenvironment in Iron Single-Atom for Fenton-like Chemistry toward Highly Efficient Wastewater Purification

Precisely identifying the atomic structures in single-atom sites and establishing authentic structure–activity relationships for single-atom catalyst (SAC) coordination are significant challenges. Here, theoretical calculations first predicted the underlying catalytic activity of Fe–N x C4–x sites w...

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Veröffentlicht in:Environmental science & technology 2023-09, Vol.57 (37), p.14046-14057
Hauptverfasser: Wu, Zelin, Huang, Bingkun, Wang, Xinhao, He, Chuan-Shu, Liu, Yang, Du, Ye, Liu, Wen, Xiong, Zhaokun, Lai, Bo
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Sprache:eng
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Catalysts
Catalytic activity
Coordination numbers
energy
hospitals
Iron
Mathematical analysis
Microenvironments
Occurrence, Fate, and Transport of Aquatic and Terrestrial Contaminants
Optimization
Reaction mechanisms
Sewage treatment
Single atom catalysts
technology
Uranium
Wastewater
Wastewater purification
Wastewater treatment
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container_end_page 14057
container_issue 37
container_start_page 14046
container_title Environmental science & technology
container_volume 57
creator Wu, Zelin
Huang, Bingkun
Wang, Xinhao
He, Chuan-Shu
Liu, Yang
Du, Ye
Liu, Wen
Xiong, Zhaokun
Lai, Bo
description Precisely identifying the atomic structures in single-atom sites and establishing authentic structure–activity relationships for single-atom catalyst (SAC) coordination are significant challenges. Here, theoretical calculations first predicted the underlying catalytic activity of Fe–N x C4–x sites with diverse first-shell coordination environments. Substituting N with C to coordinate with the central Fe atom induces an inferior Fenton-like catalytic efficiency. Then, Fe-SACs carrying three configurations (Fe–N2C2, Fe–N3C1, and Fe–N4) fabricate facilely and demonstrate that optimized coordination environments of Fe–N x C4–x significantly promote the Fenton-like catalytic activity. Specifically, the reaction rate constant increases from 0.064 to 0.318 min–1 as the coordination number of Fe–N increases from 2 to 4, slightly influencing the nonradical reaction mechanism dominated by 1O2. In-depth theoretical calculations unveil that the modulated coordination environments of Fe-SACs from Fe–N2C2 to Fe–N4 optimize the d-band electronic structures and regulate the binding strength of peroxymonosulfate on Fe–N x C4–x sites, resulting in a reduced energy barrier and enhanced Fenton-like catalytic activity. The catalytic stability and the actual hospital sewage treatment capacity also showed strong coordination dependency. This strategy of local coordination engineering offers a vivid example of modulating SACs with well-regulated coordination environments, ultimately maximizing their catalytic efficiency.
doi_str_mv 10.1021/acs.est.3c04343
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In-depth theoretical calculations unveil that the modulated coordination environments of Fe-SACs from Fe–N2C2 to Fe–N4 optimize the d-band electronic structures and regulate the binding strength of peroxymonosulfate on Fe–N x C4–x sites, resulting in a reduced energy barrier and enhanced Fenton-like catalytic activity. The catalytic stability and the actual hospital sewage treatment capacity also showed strong coordination dependency. 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Specifically, the reaction rate constant increases from 0.064 to 0.318 min–1 as the coordination number of Fe–N increases from 2 to 4, slightly influencing the nonradical reaction mechanism dominated by 1O2. In-depth theoretical calculations unveil that the modulated coordination environments of Fe-SACs from Fe–N2C2 to Fe–N4 optimize the d-band electronic structures and regulate the binding strength of peroxymonosulfate on Fe–N x C4–x sites, resulting in a reduced energy barrier and enhanced Fenton-like catalytic activity. The catalytic stability and the actual hospital sewage treatment capacity also showed strong coordination dependency. 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source ACS Publications
subjects Catalysts
Catalytic activity
Coordination numbers
energy
hospitals
Iron
Mathematical analysis
Microenvironments
Occurrence, Fate, and Transport of Aquatic and Terrestrial Contaminants
Optimization
Reaction mechanisms
Sewage treatment
Single atom catalysts
technology
Uranium
Wastewater
Wastewater purification
Wastewater treatment
title Facilely Tuning the First-Shell Coordination Microenvironment in Iron Single-Atom for Fenton-like Chemistry toward Highly Efficient Wastewater Purification
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