Research progress on preparation and energy storage properties of Sb2S3-based anode materials

被引：0

作者：

Yao H. ^{[1
]}

Li R. ^{[1
]}

Lian K. ^{[1
]}

Ji X. ^{[1
]}

Zhao T. ^{[1
]}

机构：

[1] Science and Technology on Applied Physical Chemistry Laboratory, Shaanxi Applied Physics-Chemistry Research Institute, Xi'an

来源：

Fuhe Cailiao Xuebao/Acta Materiae Compositae Sinica | 2022年 / 39卷 / 06期

关键词：

Electrochemical property; Lithium ion batteries (LIBs); Potassium ion batteries (PIBs); Sb[!sub]2[!/sub]S[!sub]3[!/sub]-based anode materials; Sodium ion batteries (SIBs);

D O I：

10.13801/j.cnki.fhclxb.20220106.001

中图分类号：

学科分类号：

摘要：

Due to the alloying/dealloying reaction mechanism in the low potential range, the theoretical discharge specific capacity of antimony sulfide (Sb2S3) material is as high as 946 mA·h·g−1, which is a promising anode mater-ial for lithium/sodium/potassium ion batteries. However, the aggregation and poor conductivity of Sb2S3 materials limit ion/electron transfer, resulting in poor electrochemical performance and severely hindering its practical application. It is necessary to summarize the structural design and lithium/sodium/potassium storage mechanism of Sb2S3-based anode materials and some important work in recent years. This article reviews the research progress of Sb2S3 based compound materials in recent years, mainly including reasonable structure design and/or combining with carbon-based materials and the electrochemical reaction mechanism involved, and puts forward the prospect of further improving Sb2S3 compound anode materials. Copyright ©2022 Acta Materiae Compositae Sinica. All rights reserved.

引用

页码：2571 / 2585

页数：14

共 75 条

[1] XIE D H, ZHANG M, WU Y, Et al., A flexible dual-ion battery based on sodium-ion quasi-solid-state electrolyte with long cycling life, Advanced Functional Materials, 30, 5, (2020)
[2] WU J X, LIU J P, CUI J, Et al., Dual-phase MoS2 as a high-performance sodium-ion battery anode, Journal of Mater-ials Chemistry A, 8, 4, pp. 2114-2122, (2020)
[3] LIANG S Z, CHENG Y J, ZHU J, Et al., A chronicle review of nonsilicon (Sn, Sb, Ge)-based Lithium/Sodium-ion battery alloying anodes, Small Methods, 4, 8, (2020)
[4] LIU Z M, WANG J, LU B A., Plum pudding model inspired KVPO4F@3DC as high-voltage and hyperstable cathode for potassium ion batteries, Science Bulletin, 65, 15, pp. 1242-1251, (2020)
[5] ZHANG Q, WANG Z J, ZHANG S L, Et al., Cathode materials for potassium-ion batteries: Current status and perspective, Electrochemical Energy Reviews, 1, 4, pp. 625-658, (2018)
[6] YANG C, XIN S, MAI L Q, Et al., Materials design for high-safety sodium-ion battery, Advanced Energy Materials, 11, 2, (2021)
[7] SARKAR A, MANOHAR C, MITRA S., A simple approach to minimize the first cycle irreversible loss of sodium titanate anode towards the development of sodium-ion battery, Nano Energy, 70, (2020)
[8] MANTHIRAM A., A reflection on lithium-ion battery cathode chemistry, Nature Communications, 11, 1, pp. 1-9, (2020)
[9] ZHANG W L, MING J, ZHAO W L, Et al., Graphitic nanocarbon with engineered defects for high-performance potassium-ion battery anodes, Advanced Functional Materials, 29, 35, (2019)
[10] WANG S, CHENG Y, XUE H, Et al., Multifunctional sulfur-mediated strategy enabling fast-charging Sb2S3 micro-package anode for lithium-ion storage, Journal of Materials Chemistry A, 9, 12, pp. 7838-7847, (2021)

← 1 2 3 4 5 6 7 8 →