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Orbital electron delocalization of axial-coordinated modified FeN4 and structurally ordered PtFe intermetallic synergistically for efficient oxygen reduction reaction catalysis.
Wu, Chenzhong; Chen, Meida; Wang, Bin; Luo, Leqing; Zhou, Qian; Mao, Guangtao; Xiong, Yuan; Wang, Qingmei.
  • Wu C; Guizhou University Key Laboratory of Green Chemical and Clean Energy Technology, Guizhou University Engineering Research Center of Efficient Utilization for Industrial Waste, Institute of Dual-carbon and New Energy Technology Innovation and Development of Guizhou Province, School of Chemistry and Ch
  • Chen M; Guizhou University Key Laboratory of Green Chemical and Clean Energy Technology, Guizhou University Engineering Research Center of Efficient Utilization for Industrial Waste, Institute of Dual-carbon and New Energy Technology Innovation and Development of Guizhou Province, School of Chemistry and Ch
  • Wang B; Guizhou University Key Laboratory of Green Chemical and Clean Energy Technology, Guizhou University Engineering Research Center of Efficient Utilization for Industrial Waste, Institute of Dual-carbon and New Energy Technology Innovation and Development of Guizhou Province, School of Chemistry and Ch
  • Luo L; Guizhou University Key Laboratory of Green Chemical and Clean Energy Technology, Guizhou University Engineering Research Center of Efficient Utilization for Industrial Waste, Institute of Dual-carbon and New Energy Technology Innovation and Development of Guizhou Province, School of Chemistry and Ch
  • Zhou Q; Guizhou University Key Laboratory of Green Chemical and Clean Energy Technology, Guizhou University Engineering Research Center of Efficient Utilization for Industrial Waste, Institute of Dual-carbon and New Energy Technology Innovation and Development of Guizhou Province, School of Chemistry and Ch
  • Mao G; Guizhou University Key Laboratory of Green Chemical and Clean Energy Technology, Guizhou University Engineering Research Center of Efficient Utilization for Industrial Waste, Institute of Dual-carbon and New Energy Technology Innovation and Development of Guizhou Province, School of Chemistry and Ch
  • Xiong Y; Guizhou University Key Laboratory of Green Chemical and Clean Energy Technology, Guizhou University Engineering Research Center of Efficient Utilization for Industrial Waste, Institute of Dual-carbon and New Energy Technology Innovation and Development of Guizhou Province, School of Chemistry and Ch
  • Wang Q; Guizhou University Key Laboratory of Green Chemical and Clean Energy Technology, Guizhou University Engineering Research Center of Efficient Utilization for Industrial Waste, Institute of Dual-carbon and New Energy Technology Innovation and Development of Guizhou Province, School of Chemistry and Ch
Chem Sci ; 15(32): 12989-13000, 2024 Aug 14.
Article en En | MEDLINE | ID: mdl-39148774
ABSTRACT
Regulating the chemical environment of materials to optimize their electronic structure, leading to the optimal adsorption energies of intermediates, is of paramount importance to improving the performance of electrocatalysts, yet remains an immense challenge. Herein, we design a harmonious axial-coordination Pt x Fe/FeN4CCl catalyst that integrates a structurally ordered PtFe intermetallic with an orbital electron-delocalization FeN4CCl support for synergistically efficient oxygen reduction catalysis. The obtained Pt2Fe/FeN4CCl with a favorable atomic arrangement and surface composition exhibits enhanced oxygen reduction reaction (ORR) intrinsic activity and durability, achieving a mass activity (MA) and specific activity (SA) of 1.637 A mgPt -1 and 2.270 mA cm-2, respectively. Detailed X-ray absorption fine spectroscopy (XAFS) further confirms the axial-coupling effect of the FeN4CCl substrate by configuring the Fe-N bond to ∼1.92 Å and the Fe-Cl bond to ∼2.06 Å. Additionally, Fourier transforms of the extended X-ray absorption fine structure (FT-EXAFS) demonstrate relatively prominent peaks at ∼1.5 Å, ascribed to the contribution of the Fe-N/Fe-Cl, further indicating the construction of the FeN4CCl moiety structure. More importantly, the electron localization function (ELF) and density functional theory (DFT) further determine an orbital electron delocalization effect due to the strong axial traction between the Cl atoms and FeN4, resulting in electron redistribution and modification of the coordination surroundings, thus optimizing the adsorption free energy of OHabs intermediates and effectively accelerating the ORR catalytic kinetic process.