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A theoretical study of atomically dispersed MN<sub>4</sub>/C (M = Fe or Mn) as a high-activity catalyst for the oxygen reduction reaction

Hao Xu, Dan Wang, Peixia Yang, Anmin Liu, Ruopeng Li, Yun Li, Lihui Xiao, Jinqiu Zhang, Maozhong An

2020Physical Chemistry Chemical Physics43 citationsDOI

Abstract

Carbon-based, non-noble metal catalysts for the oxygen reduction reaction (ORR) are crucial for the large-scale application of metal-air batteries and fuel cells. Density functional theory calculations were performed to explore the potential of atomically dispersed MN4/C (M = Fe or Mn) as an ORR catalyst in an acidic electrolyte and the ORR mechanism on MN4/C was systematically studied. The results indicated MN4 as the active site of MN4/C and a four-electron OOH transformation pathway as the preferred ORR mechanism on the MN4/C surface. The Gibbs free energy diagram showed that the rate-determining step of the FeN4/C and MnN4/C catalysts is the formation of the second H2O molecule and OOH*, respectively. FeN4/C exhibited higher thermodynamic limiting potential (0.79 V) and, thus, higher ORR activity than MnN4/C (0.52 V) in an acidic environment; its excellent catalytic performance is due to the nice electron structure and adsorption properties of the FeN4 site. Therefore, this work demonstrates that atomically dispersed MN4/C is a promising catalyst for the ORR.

Topics & Concepts

Oxygen reduction reactionCatalysisManganeseOxygenChemistryMaterials scienceInorganic chemistryCrystallographyPhysical chemistryMetallurgyElectrochemistryOrganic chemistryElectrodeElectrocatalysts for Energy ConversionFuel Cells and Related MaterialsSemiconductor materials and devices
A theoretical study of atomically dispersed MN<sub>4</sub>/C (M = Fe or Mn) as a high-activity catalyst for the oxygen reduction reaction | Litcius