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Symmetry Breaking of FeN<sub>4</sub> Moiety via Edge Defects for Acidic Oxygen Reduction Reaction

Bing Tang, Qianqian Ji, Xilin Zhang, Runchuan Shi, Jin Ma, Zechao Zhuang, Mei Sun, Huijuan Wang, Ruiqi Liu, Hengjie Liu, Chao Wang, Zhiying Guo, Lanlu Lu, Peng Jiang, Dingsheng Wang, Wensheng Yan

2025Angewandte Chemie11 citationsDOI

Abstract

Abstract Fe−N−C catalysts, with a planar D 4h symmetric FeN 4 structure, show promising as noble metal‐free oxygen reduction reaction catalysts. Nonetheless, the highly symmetric structure restricts the effective manipulation of its geometric and electronic structures, impeding further enhancements in oxygen reduction reaction performance. Here, a high proportion of asymmetric edge‐carbon was successfully introduced into Fe−N−C catalysts through morphology engineering, enabling the precise modulation of the FeN 4 active site. Electrochemical experimental results demonstrate that FeN 4 @porous carbon (FeN 4 @PC), featuring enriched asymmetric edge‐FeN 4 active sites, exhibits higher acidic oxygen reduction reaction catalytic activity compared to FeN 4 @flaky carbon (FeN 4 @FC), where symmetric FeN 4 is primarily distributed within the basal‐plane. Synchrotron X‐ray absorption spectra, X‐ray emission spectra, and theoretical calculations indicate that the enhanced oxygen reduction reaction catalytic activity of FeN 4 @PC is attributed to the higher oxidation state of Fe species in the edge structure of FeN 4 @PC. This finding paves the way for controlling the local geometric and electronic structures of single‐atom active sites, leading to the development of novel and efficient Fe−N−C catalysts.

Topics & Concepts

MoietySymmetry breakingOxygen reduction reactionChemistryOxygenPhotochemistrySymmetry (geometry)Reduction (mathematics)StereochemistryPhysical chemistryPhysicsOrganic chemistryGeometryElectrodeMathematicsElectrochemistryQuantum mechanicsElectrocatalysts for Energy ConversionMachine Learning in Materials ScienceFuel Cells and Related Materials