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高倍率钠离子电池炭包覆纳米铋负极材料

李丹马铁刘汉浩郭丽

储能科学与技术2024，Vol.13Issue(6)：1775-1785,11.

储能科学与技术2024，Vol.13Issue(6)：1775-1785,11.DOI:10.19799/j.cnki.2095-4239.2024.0002

高倍率钠离子电池炭包覆纳米铋负极材料

Carbon-coated nano-bismuth as high-rate sodium anode material

李丹 ¹马铁 ²刘汉浩 ³郭丽²

作者信息

1. 中北大学材料科学与工程学院||中北大学先进能源材料与系统研究院,山西太原 030051
2. 中北大学先进能源材料与系统研究院,山西太原 030051
3. 中北大学材料科学与工程学院
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摘要

Abstract

Bismuth has emerged as a promising anode material for sodium-ion batteries,attracting attention due to its superior ion kinetics and extended cycle life.Bismuth-based materials exhibit significant potential for enhancing energy density and charge-discharge efficiency.However,their application faces challenges due to volume expansion and the stability of the solid electrolyte interphase.These issues necessitate the development of improvements in electrical conductivity and structural stability through nanostructure design,interface engineering,and carbon coating techniques.In this study,we synthesized carbon-coated bismuth nanomaterial using a one-step carbonization method,employing a metal-organic framework of bismuth as the precursor.The bismuth particles were securely anchored to the graphene surface via C-O-Bi interfacial interactions,displaying exceptional capacity retention and stable cycling performance at high current densities.The sodium-ion storage process,dominated by pseudocapacitance,facilitates the formation of a stable solid electrolyte interphase film and enhances ion diffusion,thus improving the cycle stability and charge-discharge efficiency of the battery.The robust chemical bonds at the bismuth-graphene interfaces help maintain the structural integrity of the metal particles,buffer against volume expansion,and expedite electron diffusion,thereby boosting the electrochemical activity of the material.These findings not only provide an effective method for enhancing anode materials for batteries but also offer a new perspective for the understanding and optimization of anode materials,with significant implications for the design and development of high-performance sodium-ion battery anodes.

关键词

钠离子电池/负极/金属有机骨架/炭包覆/铋基材料

Key words

sodium ion battery/anode/metal-organic skeleton/carbon coating/bismuth-based material

分类

化学化工

引用本文复制引用

李丹,马铁,刘汉浩,郭丽..高倍率钠离子电池炭包覆纳米铋负极材料[J].储能科学与技术,2024,13(6):1775-1785,11.

基金项目

山西省自然科学研究面上项目(202203021221116),山西省自然科学研究青年项目(201901D211215). （202203021221116）

储能科学与技术

OA北大核心CSTPCD

ISSN：2095-4239

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