Research progress on the prelithiation technology of alloy-type anodes

doi:10.19799/j.cnki.2095-4239.2021.0570

Abstract

Abstract:

The anode is a key component of lithium-ion batteries, and the use of high-capacity alloy-type anodes can significantly improve the energy density of those batteries. However, alloy-type anodes suffer from low initial coulombic efficiency. This problem leads to irreversible consumption of large quantities of active lithium, which offsets the improved battery energy density. Prelithiation technology is considered a promising approach to address this problem, applicable both to anodes and cathodes. This paper summarizes research progress and application prospects for different prelithiation technologies based on a comprehensive analysis of recent literature. For anode prelithiation, the strategies of electrochemical prelithiation, chemical prelithiation, lithium-rich anode additives, and direct contact with metallic lithium, are introduced. For cathode prelithiation, strategies involving lithium-rich additives and over-lithiation are discussed. With a view toward the practical realization of different prelithiation technologies, this analysis focuses on the stability and safety, utilization rate, and cost of each prelithiation reagent. Results demonstrate that prelithiation can be an effective solution to compensate for irreversible capacity loss. Thus, it can contribute to significant improvements in energy density and cycle life of lithium-ion batteries with alloy anodes. Low cost and high safety are the keys to promote the practical application of prelithiation technology.

Key words: pre-lithiation, coulombic efficiency, silicon anode, high energy density, lithium-ion batteries

CLC Number:

TM 911

Ce ZHANG, Siwu LI, Jia XIE. Research progress on the prelithiation technology of alloy-type anodes[J]. Energy Storage Science and Technology, 2022, 11(5): 1383-1400.

Figures/Tables 13

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负极	方法	电池体系	预锂化前ICE	预锂化后ICE	循环性能	参考文献
c-SiO _x	电化学	NCA\|\|c-SiO _x	58.85%	85.34%	61%(1 C, 100圈)	[10]
SiO _x	接触金属锂	NCM622\|\|SiO _x	68%	87%	74%(200圈)	[16]
P/C	Li-Bp/THF 0.41 V (vs. Li/Li⁺)	P/C\|\|Li	74%	94%	—	[28]
SiO _x /C	Li-Bp/THF 0.41 V (vs. Li/Li⁺)	SiO _x /C\|\|Li	75.6%	90%	～58%(0.5 C, 400圈)	[40]
Si	Li-Naph/DME 0.35 V (vs. Li/Li⁺)	Si\|\|Li	74%	96.1%	—	[29]
SiO _x	Li-Arene <0.2 V (vs. Li/Li⁺)	NCM532\|\|SiO _x	37.8%	86.4%	—	[36]
c-Gr/Si	Li-Bp/2-Me-THF 0.08 V (vs. Li/Li⁺)	NCM622\|\| c-Gr/Si	63.2%	88.3%	87.3%(250圈)	[38]
Sn	机械辊压	LFP\|\|Sn	21%	94%	94.5%(200圈)	[39]
Si-CNT	SLMP	Si-CNT\|\|Li	58%	79%	—	[51]
Si	Li@eGF	Si\|\|Li	79.4%	100.5%	56%(0.05 C, 100圈)	[52]
Si	Li _x Si-Li₂O	Si\|\|Li	76%	94%	—	[65]

补锂试剂	容量	电池	补锂前首圈充电容量	添加量/(%，质量分数)	补锂后首圈充电容量	参考文献
Li₃N	1399.3 mAh/g (截止电位4.2 V)	LCO\|\|Li	149.7 mAh/g	2	178.4 mAh/g	[69]
Fe/LiF/Li₂O	550 mAh/g (截止电位4.4 V)	NCM622\|\|Li	198 mAh/g	4.8	229 mAh/g	[81]
Li₂S-PAN	668 mAh/g (截止电位4.0 V)	LFP\|\|Li	169 mAh/g	4.3	187 mAh/g	[71]
Co/Li₂O	619 mAh/g (截止电位4.1 V)	LFP\|\|Li	163 mAh/g	4.8	183 mAh/g	[70]
Li₃P/rGO (5:1)	1289.7 mAh/g (理论)	LFP\|\|Li	162 mAh/g	5	181.3 mAh/g	[72]
Li₅FeO₄	764 mAh/g (截止电位4.7 V)	NCM523\|\|Li	190 mAh/g	7.1	233 mAh/g	[94]
NiO/Li₂CO₃	240 mAh/g (截止电位4.5 V)	LMO\|\|Li	120 mAh/g	50	410 mAh/g	[87]
Li_1.62Ni_0.5Mn_1.5O₄	截止电位4.55 V	LMO\|\|Li	145 mAh/g	—	217 mAh/g	[96]

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