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Coordination engineering of heterogeneous high-valent Fe(IV)-oxo for safe removal of pollutants via powerful Fenton-like reactions

Yuanfang Lin, Ying Wang, Zongling Weng, Yang Zhou, Siqi Liu, Xinwen Ou, Xing Xu, Yanpeng Cai, Jin Jiang, Bin Han, Zhifeng Yang

2024Nature Communications178 citationsDOIOpen Access PDF

Abstract

Coordination engineering of high-valent Fe(IV)-oxo (FeIV=O) is expected to break the activity-selectivity trade-off of traditional reactive oxygen species, while attempts to regulate the oxidation behaviors of heterogeneous FeIV=O remain unexplored. Here, by coordination engineering of Fe-Nx single-atom catalysts (Fe-Nx SACs), we propose a feasible approach to regulate the oxidation behaviors of heterogeneous FeIV=O. The developed Fe-N2 SACs/peroxymonosulfate (PMS) system delivers boosted performance for FeIV=O generation, and thereby can selectively remove a range of pollutants within tens of seconds. In-situ spectra and theoretical simulations suggest that low-coordination Fe-Nx SACs favor the generation of FeIV=O via PMS activation as providing more electrons to facilitate the desorption of the key *SO4H intermediate. Due to their disparate attacking sites to sulfamethoxazole (SMX) molecules, Fe-N2 SACs mediated FeIV=O (FeIVN2=O) oxidize SMX to small molecules with less toxicity, while FeIVN4=O produces series of more toxic azo compounds through N-N coupling with more complex oxidation pathways. Coordination engineering of high-valent Fe(IV)-oxo may break the activity-selectivity trade-off of traditional reactive oxygen species but the controllable generation of heterogeneous FeIV=O remains unexplored. Here, the authors alter the coordination number of Fe-Nx single-atom catalysts to regulate oxidation behaviors of heterogeneous FeIV=O.

Topics & Concepts

CatalysisChemistrySelectivityDesorptionMoleculePollutantOxygenPhotochemistryCombinatorial chemistryAdsorptionOrganic chemistryAdvanced oxidation water treatmentAdvanced Photocatalysis TechniquesAdvanced Nanomaterials in Catalysis