Axial coordination tuning Fe single-atom catalysts for boosting H2O2 activation

Haoyang Fu; Jiaqi Wei; Guoliang Chen; Minkai Xu; Jiyuan Liu; Jianghong Zhang; Ke Li; Qianyu Xu; Yunjie Zou; Wei xian Zhang; Shibo Xi; Xiaodong Chen; Shuzhou Li; Lan Ling

doi:10.1016/j.apcatb.2022.122012

Axial coordination tuning Fe single-atom catalysts for boosting H₂O₂ activation

Haoyang Fu, Jiaqi Wei, Guoliang Chen, Minkai Xu, Jiyuan Liu, Jianghong Zhang, Ke Li, Qianyu Xu, Yunjie Zou, Wei xian Zhang, Shibo Xi, Xiaodong Chen, Shuzhou Li^*, Lan Ling^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

56 Citations (Scopus)

Abstract

Precisely regulating the coordination microenvironment of single-atom catalysts (SACs) to achieve enhanced reactivity is significant and desired but still in its infancy. Herein, a coordination-tuned and pyrolysis-free strategy is reported for the fabrication of a Fenton-like SAC containing the axial five-coordinated configuration (Fe–N₅). The N species on the N-doped graphene act as anchoring points for iron phthalocyanine (a typical Fe–N₄ complex) to obtain isolated Fe–N₅ sites, which significantly modulates the electronic state of Fe atoms and lowers the H₂O₂ activation barrier for •OH production. Moreover, the enriched pyridinic N serve as contaminant adsorption sites shortening •OH diffusion distance, establishing a dual-site reaction mechanism with Fe–N₅ sites. As such, the Fe–N₅ catalyst exhibits exceptional Fenton activity towards catalytic oxidation of phenol (k = 0.180 min⁻¹). Our work unravels the dependence of Fenton activity on the single-atom coordination environment and provides a platform for precise engineering of SACs.

Original language	English
Article number	122012
Journal	Applied Catalysis B: Environmental
Volume	321
DOIs	https://doi.org/10.1016/j.apcatb.2022.122012
Publication status	Published - Feb 2023
Externally published	Yes

Bibliographical note

Publisher Copyright:
© 2022 Elsevier B.V.

ASJC Scopus Subject Areas

Catalysis
General Environmental Science
Process Chemistry and Technology

Keywords

Axiel coordination
Fenton-like reaction
Fe–N catalytic sites
Single-atom catalysts
Wastewater treatment

Access to Document

10.1016/j.apcatb.2022.122012

Cite this

@article{e77095571e3f401393323943fc3d7702,

title = "Axial coordination tuning Fe single-atom catalysts for boosting H2O2 activation",

abstract = "Precisely regulating the coordination microenvironment of single-atom catalysts (SACs) to achieve enhanced reactivity is significant and desired but still in its infancy. Herein, a coordination-tuned and pyrolysis-free strategy is reported for the fabrication of a Fenton-like SAC containing the axial five-coordinated configuration (Fe–N5). The N species on the N-doped graphene act as anchoring points for iron phthalocyanine (a typical Fe–N4 complex) to obtain isolated Fe–N5 sites, which significantly modulates the electronic state of Fe atoms and lowers the H2O2 activation barrier for •OH production. Moreover, the enriched pyridinic N serve as contaminant adsorption sites shortening •OH diffusion distance, establishing a dual-site reaction mechanism with Fe–N5 sites. As such, the Fe–N5 catalyst exhibits exceptional Fenton activity towards catalytic oxidation of phenol (k = 0.180 min−1). Our work unravels the dependence of Fenton activity on the single-atom coordination environment and provides a platform for precise engineering of SACs.",

keywords = "Axiel coordination, Fenton-like reaction, Fe–N catalytic sites, Single-atom catalysts, Wastewater treatment",

author = "Haoyang Fu and Jiaqi Wei and Guoliang Chen and Minkai Xu and Jiyuan Liu and Jianghong Zhang and Ke Li and Qianyu Xu and Yunjie Zou and Zhang, {Wei xian} and Shibo Xi and Xiaodong Chen and Shuzhou Li and Lan Ling",

note = "Publisher Copyright: {\textcopyright} 2022 Elsevier B.V.",

year = "2023",

month = feb,

doi = "10.1016/j.apcatb.2022.122012",

language = "English",

volume = "321",

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T1 - Axial coordination tuning Fe single-atom catalysts for boosting H2O2 activation

AU - Fu, Haoyang

AU - Wei, Jiaqi

AU - Chen, Guoliang

AU - Xu, Minkai

AU - Liu, Jiyuan

AU - Zhang, Jianghong

AU - Li, Ke

AU - Xu, Qianyu

AU - Zou, Yunjie

AU - Zhang, Wei xian

AU - Xi, Shibo

AU - Chen, Xiaodong

AU - Li, Shuzhou

AU - Ling, Lan

PY - 2023/2

Y1 - 2023/2

N2 - Precisely regulating the coordination microenvironment of single-atom catalysts (SACs) to achieve enhanced reactivity is significant and desired but still in its infancy. Herein, a coordination-tuned and pyrolysis-free strategy is reported for the fabrication of a Fenton-like SAC containing the axial five-coordinated configuration (Fe–N5). The N species on the N-doped graphene act as anchoring points for iron phthalocyanine (a typical Fe–N4 complex) to obtain isolated Fe–N5 sites, which significantly modulates the electronic state of Fe atoms and lowers the H2O2 activation barrier for •OH production. Moreover, the enriched pyridinic N serve as contaminant adsorption sites shortening •OH diffusion distance, establishing a dual-site reaction mechanism with Fe–N5 sites. As such, the Fe–N5 catalyst exhibits exceptional Fenton activity towards catalytic oxidation of phenol (k = 0.180 min−1). Our work unravels the dependence of Fenton activity on the single-atom coordination environment and provides a platform for precise engineering of SACs.

AB - Precisely regulating the coordination microenvironment of single-atom catalysts (SACs) to achieve enhanced reactivity is significant and desired but still in its infancy. Herein, a coordination-tuned and pyrolysis-free strategy is reported for the fabrication of a Fenton-like SAC containing the axial five-coordinated configuration (Fe–N5). The N species on the N-doped graphene act as anchoring points for iron phthalocyanine (a typical Fe–N4 complex) to obtain isolated Fe–N5 sites, which significantly modulates the electronic state of Fe atoms and lowers the H2O2 activation barrier for •OH production. Moreover, the enriched pyridinic N serve as contaminant adsorption sites shortening •OH diffusion distance, establishing a dual-site reaction mechanism with Fe–N5 sites. As such, the Fe–N5 catalyst exhibits exceptional Fenton activity towards catalytic oxidation of phenol (k = 0.180 min−1). Our work unravels the dependence of Fenton activity on the single-atom coordination environment and provides a platform for precise engineering of SACs.

KW - Axiel coordination

KW - Fenton-like reaction

KW - Fe–N catalytic sites

KW - Single-atom catalysts

KW - Wastewater treatment

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