Efficient Fe[sub.3]C-CF Cathode Catalyst Based on the Formation/Decomposition of Li[sub.2−x]O[sub.2] for Li-O[sub.2] Batteries

Lithium-oxygen batteries have attracted considerable attention in the past several years due to their ultra-high theoretical energy density. However, there are still many serious issues that must be addressed before considering practical applications, including the sluggish oxygen redox kinetics, th...

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Published in:Molecules (Basel, Switzerland) Switzerland), 2023-07, Vol.28 (14)
Main Authors: Yi, Guanyu, Li, Gaoyang, Jiang, Shuhuai, Zhang, Guoliang, Guo, Liang, Zhang, Xiuqi, Zhao, Zhongkui, Zou, Zhongping, Ma, Hailong, Fu, Xiaojiao, Liu, Yan, Dang, Feng
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Batteries
Electrolytes
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container_issue 14
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container_title Molecules (Basel, Switzerland)
container_volume 28
creator Yi, Guanyu
Li, Gaoyang
Jiang, Shuhuai
Zhang, Guoliang
Guo, Liang
Zhang, Xiuqi
Zhao, Zhongkui
Zou, Zhongping
Ma, Hailong
Fu, Xiaojiao
Liu, Yan
Dang, Feng
description Lithium-oxygen batteries have attracted considerable attention in the past several years due to their ultra-high theoretical energy density. However, there are still many serious issues that must be addressed before considering practical applications, including the sluggish oxygen redox kinetics, the limited capacity far from the theoretical value, and the poor cycle stability. This study proposes a surface modification strategy that can enhance the catalytic activity by loading Fe[sub.3]C particles on carbon fibers, and the microstructure of Fe[sub.3]C particle-modified carbon fibers is studied by multiple materials characterization methods. Experiments and density functional theory (DFT) calculations show that the discharge products on the Fe[sub.3]C carbon fiber (Fe[sub.3]C-CF) cathode are mainly Li[sub.2−x]O[sub.2]. Fe[sub.3]C-CF exhibits high catalytic ability based on its promotion of the formation/decomposition processes of Li[sub.2−x]O[sub.2]. Consequently, the well-designed electrode catalyst exhibits a large specific capacity of 17,653.1 mAh g[sup.−1] and an excellent cyclability of 263 cycles at a current of 200 mA g[sup.−1].
doi_str_mv 10.3390/molecules28145597
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However, there are still many serious issues that must be addressed before considering practical applications, including the sluggish oxygen redox kinetics, the limited capacity far from the theoretical value, and the poor cycle stability. This study proposes a surface modification strategy that can enhance the catalytic activity by loading Fe[sub.3]C particles on carbon fibers, and the microstructure of Fe[sub.3]C particle-modified carbon fibers is studied by multiple materials characterization methods. Experiments and density functional theory (DFT) calculations show that the discharge products on the Fe[sub.3]C carbon fiber (Fe[sub.3]C-CF) cathode are mainly Li[sub.2−x]O[sub.2]. Fe[sub.3]C-CF exhibits high catalytic ability based on its promotion of the formation/decomposition processes of Li[sub.2−x]O[sub.2]. 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Electrolytes
title Efficient Fe[sub.3]C-CF Cathode Catalyst Based on the Formation/Decomposition of Li[sub.2−x]O[sub.2] for Li-O[sub.2] Batteries
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