Zinc-motivated Fe/Fe5C2/Fe1−xS@Fe–N–C active sites grown on N-doped porous carbon toward efficient oxygen reduction reaction in zinc-air batteries

Qilong Ye; Mengwei Li; Sanying Hou; Yijie Deng; Junming Luo; Xinlong Tian

doi:10.1039/d2dt03699a

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Zinc-motivated Fe/Fe₅C₂/Fe_1−xS@Fe–N–C active sites grown on N-doped porous carbon toward efficient oxygen reduction reaction in zinc-air batteries

Qilong Ye Mengwei Li Sanying Hou Yijie Deng Junming Luo Xinlong Tian

Year: 2023 Journal: Dalton Transactions Vol: 52 (9)Pages: 2684-2692 Publisher: Royal Society of Chemistry

DOI: 10.1039/d2dt03699a

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Abstract

An Fe/Fe 5 C 2 /Fe 1− x S@Fe–N–C embedded in porous carbon electrocatalyst with good oxygen reduction reaction activity is prepared via a facile solid-phase strategy.

Keywords:

Zinc Doping Carbon fibers Materials science Crystallography Porosity Analytical Chemistry (journal) Inorganic chemistry Chemistry Metallurgy Composite number

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Electrocatalysts for Energy Conversion

Physical Sciences → Energy → Renewable Energy, Sustainability and the Environment

Advanced battery technologies research

Physical Sciences → Engineering → Electrical and Electronic Engineering

Supercapacitor Materials and Fabrication

Physical Sciences → Materials Science → Electronic, Optical and Magnetic Materials

Zinc-motivated Fe/Fe₅C₂/Fe_1−xS@Fe–N–C active sites grown on N-doped porous carbon toward efficient oxygen reduction reaction in zinc-air batteries

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