Na-ion batteries: From fundamental research to engineering exploration

doi:10.19799/j.cnki.2095-4239.2020.0054

Abstract

Abstract:

With the increasing demand for low-cost energy storage systems, more and more researchers and engineers have been involved in the fundamental research and engineering exploration of Na-ion batteries (NIBs), which grew rapidly in the past decade. This article firstly analyzes the situation of global lithium resource, especially the potential risks in China. Then we review the history of NIBs and introduce their global industrialization status in recent years. According to the latest research progress in this field, we summarize seven advantages of NIBs in terms of cost, performance, etc., which endows NIBs with huge development potential. Finally, we focus on introducing our work on the development and mass production of low-cost electrode materials such as copper-based layered oxide cathodes and disordered carbon anodes, as well as the application demonstration and engineering scale-up of NIBs. The successful demonstration of Ah-grade cells and battery packs for NIBs has initially proved their feasibility. By optimizing electrode materials, electrolytes, manufacturing and integration, and battery management, it is expected to further improve the comprehensive performance of NIBs, and realize the practical applications in low-speed electric vehicles, data center backup power supplies, communication base stations, household/industrial energy storage systems, and large-scale energy storage.

Key words: Na-ion battery, cathode material, anode material, energy storage

CLC Number:

TM 911

RONG Xiaohui, LU Yaxiang, QI Xingguo, ZHOU Quan, KONG Weihe, TANG Kun, CHEN Liquan, HU Yongsheng. Na-ion batteries: From fundamental research to engineering exploration[J]. Energy Storage Science and Technology, 2020, 9(2): 515-522.

Figures/Tables 7

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Table 1

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References 24

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指标	铅酸电池	锂离子电池（磷酸铁锂/石墨体系）	钠离子电池（铜基氧化物/煤基碳体系）
质量能量密度^①	30~50 W·h/kg	120~180 W·h /kg	100~150 W·h /kg
体积能量密度^①	60~100 W·h /L	200~350 W·h /L	180~280 W·h /L
单位能量原料成本^②,③	0.40元/ W·h	0.43元/W·h	0.29元/(W·h)
循环寿命^①	300~500次	3000次以上	2000次以上
平均工作电压^①	2.0 V	3.2 V	3.2 V
-20^oC容量保持率	小于60%	小于70%	88%以上
耐过放电	差	差	可放电至0 V
安全性	优	优	优
环保特性	差	优	优

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