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Unveiling the coupling effect of sp2 domain size and local active sites in switching the selectivity of nanocarbon catalysts toward the oxygen electro-reduction

Chao-Wei Yang, Fei Sun, Yi Zhang, Zhibin Qu, Jiayu Zuo, Wei Zhou, Jihui Gao, Shaoqin Liu, Yunfeng Lu

2025Nature Communications6 citationsDOIOpen Access PDF

Abstract

Carbon-mediated active site engineering has demonstrated remarkable electrocatalytic activities for oxygen reduction reactions (ORR), yet the relationship between carbonaceous structure and ORR selectivity remains unclear. Herein, we show that local active sites and sp2 domain size jointly regulate ORR selectivity. Specifically, we demonstrate that while local active sites determine the rate-limiting intermediate type (from O2−* to OOH*), increasing sp2 domain size can either promote OOH* formation and subsequent O-O bond dissociation or facilitate OOH* consumption to enhance the reaction rate, all of which enable the ORR pathway to switch from 2e− to 4e−. This coupling is also validated using nitrogen-doped carbon soot to induce a profound change in ORR selectivity, where the synergistic interplay between small carbon domain sizes and nitrogen dopants boosts the 2e− selectivity from ~50% to over 90%. Ultimately, p-band theory integrates these coupling mechanisms, offering a fundamental principle for designing highly selective nanocarbon electrocatalysts. Carbon-mediated oxygen reduction is promising, yet the structure-selectivity relationship remains unclear. The authors now show that the synergy between carbon domain size and active site engineering switches the reaction selectivity, offering a fundamental principle for rational catalyst design.

Topics & Concepts

SelectivityCatalysisActive siteDissociation (chemistry)ChemistryOxygenCoupling (piping)DopantCarbon fibersMaterials scienceNanotechnologyOxygen reduction reactionCoupling reactionSootChemical physicsCombinatorial chemistryChemical engineeringPhotochemistryDensity functional theoryRational designElectrocatalystDomain (mathematical analysis)Active oxygenHeterogeneous catalysisElectrocatalysts for Energy ConversionCO2 Reduction Techniques and CatalystsAmmonia Synthesis and Nitrogen Reduction
Unveiling the coupling effect of sp2 domain size and local active sites in switching the selectivity of nanocarbon catalysts toward the oxygen electro-reduction | Litcius