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Enhancing the ORR durability of single atomic Fe-N4 active sites with implanted SiO2 nanoparticles as radical and H2O2 inhibitors

Maosong Liu, Zhihao Lei, Xianhe Lv, Xiaoxue Song, Long Zhang, Shun Li, Tao Sun, Li Li, Jianing Hui, Wenyong Zhang, Siew Yee Wong, Xu Li, Guang‐Jie Xia, Jianming Zhang, Shuhui Sun

2025Nature Communications11 citationsDOIOpen Access PDF

Abstract

Highly efficient and durable single-atom catalysts (SACs) hold great promise for improving oxygen reduction reaction (ORR) in metal-air batteries and fuel cells. However, their long-term stability is challenged by the byproducts such as H2O2 and undesirable radicals. Herein, we report a Fe-N4 active center-based SAC decorated with SiO2 nanoparticles (NPs) as a radical scavenger, which was prepared using coffee grounds and industrial spent acid residue. The presence of SiO2 NPs effectively suppresses the electrochemical H2O2 production, significantly improving durability with only a 5 mV half-wave potential loss after 30,000 voltage cycles in alkaline media. Electrochemical evaluations, in-situ characterizations, and density functional theory calculations reveal that the Fe-O-Si binding at the SiO2–Fe-N4 interface strengthens the binding of OOH* species, facilitating the 4-electron selectivity in ORR while inhibiting the formation of H2O2 and reactive oxygen species. Additionally, the SiO2 NPs prevent the aggregation of Fe single atomic sites, thereby stabilizing the SAC active sites. Therefore, the incorporation of SiO2 NP into Fe-based SAC offers a straightforward and effective strategy for enhancing ORR performance. The authors report a Fe–N4 single-atom catalyst decorated with SiO2 nanoparticles acting as radical scavengers, which reduce harmful byproducts and stabilize active sites, improving durability and activity for oxygen reduction.

Topics & Concepts

CatalysisElectrochemistryNanoparticleDurabilityChemistryOxygen reduction reactionSelectivityReactive oxygen speciesCombinatorial chemistryOxygenNanotechnologyOxygen reductionElectrocatalystChemical engineeringDensity functional theoryActive siteMaterials scienceFuel cellsHydroxyl radicalRedoxReduction (mathematics)Chemical stabilityElectrocatalysts for Energy ConversionAdvanced battery technologies researchAdvanced Battery Materials and Technologies
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