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Axial orbital hybridization enables single-atom Fe-N-C hollow microplates for efficient oxygen reduction

Fei-Xiang Ma, Jianghua Wu, Xiongyi Liang, Guobin Zhang, Zheng-Qi Liu, Hong-Shuang Fan, Jian Lu, Cheng‐Yan Xu, Xiao Cheng Zeng, Yang Yang Li

2026Science China Materials6 citationsDOIOpen Access PDF

Abstract

Abstract Metal single-atoms with optimized coordination structure on highly accessible substrate can maximize the metal utilization efficiency along with enhancing catalytic activities. Herein, axial nitrogen-coordinated Fe-N 5 sites on N-doped carbon (denoted as FeN 5 @N-C) hollow microplates are fabricated via a unique Fe 3+ -chelated polydopamine assisted hollowing strategy using ZIF-L microplates as multifunctional templates. Due to the powerful chelating and adhesive ability of polydopamine, this hollow-carbon strategy can be extended to fabricate single-atom Fe-N-C hollow structures with different shapes and encapsulate other transition-metal single atoms (Ni, Co, Mn, and Cu) into the N-doped carbon hollow microplates. The FeN 5 @N-C hollow microplates exhibit outstanding oxygen reduction reaction (ORR) capability with an impressive half-wave potential of 0.93 V vs. reversible hydrogen electrode and high stability, which can serve as air-cathode catalysts for high-performance Zn-air batteries with high peak power density of 225.3 mW cm −2 and stable cyclability of up to 400 h. Comprehensive analysis and theoretical calculations elucidate that axial nitrogen coordination in Fe-N 5 catalytic sites, unlike the planar Fe-N 4 configuration, can compete well with the bonding of OH* through additional 3d-2p orbital hybridization, thereby giving moderate bonding strength to enhance the ORR activity.

Topics & Concepts

Materials scienceCatalysisElectrodeSubstrate (aquarium)PlanarCarbon fibersOxygen reduction reactionNanotechnologyMetalChemical engineeringOxygenHydrogenReversible hydrogen electrodeHydrogen bondPower densityCurrent densityOxygen reductionTemplate method patternChelationNitrogenOrbital hybridisationElectrocatalysts for Energy ConversionAmmonia Synthesis and Nitrogen ReductionAdvanced battery technologies research
Axial orbital hybridization enables single-atom Fe-N-C hollow microplates for efficient oxygen reduction | Litcius