Recent advances in presodiation strategies for sodium-ion batteries

doi:10.19799/j.cnki.2095-4239.2024.1069

Abstract

Abstract:

Sodium-ion batteries are emerging as one of the most promising energy storage systems beyond lithium-ion batteries, holding great potential for widespread adoption. However, their development is hindered by a low initial Coulombic efficiency (ICE). Sodium supplementation is recognized as an effective strategy to address this issue, playing a critical role in advancing the commercialization of sodium-ion batteries. This article reviews the research progress of presodium technologies worldwide It examines advancements from three key perspectives, namely cathodes, electrolytes, and anodes. For the cathodes, sodium supplementation methods include direct impregnation, sacrificing additives, and electrochemical treatment. The optimization of electrolytes primarily focuses on improving sodium salts and solvents, balancing their proportions, and incorporating additives. For anodes, sodium supplementation techniques include direct sodium supplementation, electrochemical presodium method, hard carbon modification. This review summarizes the current progress of sodium supplement technology, elaborates on their advantages and disadvantages, evaluates their commercial viability, and offers guidance for the development of sodium supplementation strategies in sodium-ion batteries.

Key words: presodium, sodium-ion battery, additive, initial Coulombic efficiency

CLC Number:

TM 911.3

Congqing TANG, Jingsheng CAI. Recent advances in presodiation strategies for sodium-ion batteries[J]. Energy Storage Science and Technology, 2025, 14(5): 1884-1899.

Figures/Tables 17

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Table 1

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Table 2

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添加剂名词	截止电压/V	理论容量/(mAh/g)	实际容量/(mAh/g)	参考文献
NaN₃	4.2	412	300	[8]
Na₂S	4.1	687	687	[3]
Na₃P	4.3	804	600	[9]
NaCrO₂	4.2	251	229	[10]
Na₂NiO₂	3.6	392	285	[11]
Na₂CO₃	4.2	506	110	[12]
NaNO₂	4.3	427	350	[13]
Na₂C₂O₄	4.6	400	386.8	[14]
Na₂C₄O₄	4.1	339	230	[14-18]
Na₂C₆O₆	4.5	250	360	[14-15]
Na₂C₆H₂O₆	4.5	248	265	[19]
EDTA-4Na	4.5	237	420	[4]
DTPA-5Na	4.3	266	363	[20]
Na₂O	2.5~4.2	864	500	[21]
Na₂O₂	4	687	421	[22]
NaNH₂	3.8	686	680	[23]
CH₃COONa	4.18	326	302	[24]
PABZ-Na	3.45	168	160	[25]
Na₂C₃O₅	4	331	310	[3]

序号	材料名称	首圈充/放电/(mAh/g)	ICE	容量保持率	参考文献
1	联苯钠掺杂硬碳	300/301	99.6%	60%(500圈)	[63]
2	预锂化硬碳	200/239	92.0%	85%(1000圈)	[64]
3	预钠化碳分子筛	200/285	70.0%	81%(500圈)	[65]
4	预钠化生物质碳	283/478	59.2%	82%(900圈)	[66]

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