水系锌离子电池的研究进展

doi:10.15541/jim20160192

无机材料学报 ›› 2017, Vol. 32 ›› Issue (3): 225-234.DOI: 10.15541/jim20160192

• • 下一篇

水系锌离子电池的研究进展

陈丽能, 晏梦雨, 梅志文, 麦立强

(武汉理工大学材料复合新技术国家重点实验室, 武汉 430070)

收稿日期:2016-03-28 修回日期:2016-06-16 出版日期:2017-03-20 网络出版日期:2017-02-24
作者简介:陈丽能(1991–), 女, 博士研究生. E-mail: clnsmiles@whut.edu.cn
基金资助:
科技部“国家国际科技合作计划”(2013DFA50840);科技部“国家重大科学研究计划课题” (2013CB934103);国家自然科学基金杰出青年基金(51425204);湖北省杰出青年基金(2014CFA035);国家自然科学基金创新研究群体(51521001)

Research Progress and Prospect of Aqueous Zinc Ion Battery

CHEN Li-Neng, YAN Meng-Yu, MEI Zhi-Wen, MAI Li-Qiang

(State Key Laboratory of Advanced Technology for Materials Synthesis and Processing, Wuhan University of Technology, Wuhan 430070, China)

Received:2016-03-28 Revised:2016-06-16 Published:2017-03-20 Online:2017-02-24
About author:CHEN Li-Neng. E-mail: clnsmiles@whut.edu.cn
Supported by:
National Basic Research Program of China (2013DFA50840);International Science & Technology Cooperation Program of China (2013CB934103);National Natural Science Fund for Distinguished Young Scholars(51425204);The Hubei Provincial Natural Science Fund for Distinguished Young Scholars (2014CFA035);National Natural Science Foundation of China (51521001)

摘要/Abstract

摘要：

锌离子电池是近年来发展起来的一种新型二次水系电池, 具有高能量密度、高功率密度、放电过程高效安全、电池材料无毒廉价、制备工艺简单等优点, 在大型储能等领域具有很高应用价值和发展前景。本文综述了水系锌离子电池的研究进展, 对金属锌作负极的优点和面临的处理问题进行总结, 对已报导的正极材料中锌离子电池的电化学性能和反应机制进行分析, 并通过分析目前多价离子的脱嵌特性对锌离子电池正极材料的发展进行预测。

关键词: 水系锌离子电池, 正极材料, 高功率密度, 能量储存, 综述

Abstract:

Zinc ion battery, a new type of aqueous secondary batteries proposed in recent years, can deliver high energy and high power density. Meanwhile, safe and efficient discharge processes, cheap and nontoxic electrode materials, and easy fabrication are the advantage of Zinc ion battery, showing great practical value and developmental prospects in the field of scale energy storage. In this paper, the development and exploration of aqueous zinc ion battery are reviewed. Also the advantages and challenges of the zinc anode are summarized. Moreover, this paper analyzed the electrochemical properties and reaction mechanism specifically. In addition, the development of cathode materials is predicted by analyzing the insertion and extraction of multivalent ions.

Key words: aqueous zinc ion battery, cathode materials, high power density, energy storage, review

中图分类号:

TQ15

陈丽能, 晏梦雨, 梅志文, 麦立强. 水系锌离子电池的研究进展[J]. 无机材料学报, 2017, 32(3): 225-234.

CHEN Li-Neng, YAN Meng-Yu, MEI Zhi-Wen, MAI Li-Qiang. Research Progress and Prospect of Aqueous Zinc Ion Battery[J]. Journal of Inorganic Materials, 2017, 32(3): 225-234.

图/表 13

图1 锌离子电池的电化学原理图[9]

Fig. 1 Schematic illustration of the electrochemical principle of the zinc ion battery[9]

图2 锌离子电池和其它储能器件的Ragone图

Fig. 2 Ragone plots of zinc ion battery and other energy storage devices

图3 锌离子电池在0.1 A/g (a)和8 A/g (b)恒电流下的充放电循环曲线[9]

Fig. 3 Charge and discharge curues of zinc ion batteries at current density of 0.1 A/g (a) and 8 A/g (b)[9]

图4 锌与其他金属作空气电池的比能量和在水中的稳定性[40]

Fig. 4 Specific capacity metal-air battery and stability in water of zinc and other metals[40]

图5 (a)200 mA h/g的电流密度下未改性及加入不同比例活性炭改性的锌负极后锌离子电池的循环性能; (b) 0.1 mV/s扫描速度下未改性和活性炭改性锌负极的锌离子电池的循环伏安曲线[45]

Fig. 5 (a) Cycling performance of rechargeable zinc ion batteries with the unmodified ZnAB and ZnAB+AC (charge/discharge at 200 mA h/g); (b) CV curves of the unmodified ZnAB and ZnAB+12wt%AC at scanning rate of 0.1 mV/s[45]

图6 (a) 不同倍率下锌离子电池的放电曲线; (b) 6C倍率下锌离子电池的循环性能[9]

Fig. 6 (a) Discharge curves of the zinc ion battery at various rates and (b) cycle life performance of the zinc ion battery at a continuous cycling 6C/6C charge/discharge test[9]

图7 (a)锌离子电池第1圈(黑)、第2圈(红)的循环伏安曲线和循环性能曲线; (b)充放电不同阶段时锌负极的XRD图谱: 原电极(1), 半放电(2), 完全放电(3), 完全充电(4), 重新放电(5), 与图(a)中表示对应[68]

Fig. 7 Potential profiles of the zinc/α-MnO2 Zn-ion battery during the first (black line) and the second (red line) cycles, and their cycling performance up to 30 cycles (inset). (b) Ex-situ X-ray diffraction patterns of the electrodes at various charge and discharge stages: original electrode (1), half discharged electrode (2), fully discharged electrode (3), fully recharged electrode (4), and fully re-discharged electrode (5), as indicated in Figure (a)[68]

图8 锌离子嵌入γ-MnO2结构的示意图[63]

Fig. 8 Schematic illustration of the reaction pathway of Zn-insertion in the prepared γ-MnO2 cathode[63]

图9 (a)不同比例V2O5/C做电极时电池的循环伏安曲线; (b)V2O5/C做电极时电池循环第1圈和第20圈的循环伏安曲线[44]

Fig. 9 (a) Cycle voltammograms of composite electrodes with different mass ratios of V2O5/C and (b) cycle performance of composite electrodes[44]

图10 (a)电流密度为60 mA/g时电池的循环性能曲线; (b)不同倍率情况下电池的循环性能曲线[73]

Fig. 10 (a) Capacity versus number of cycles of the full cell at the current density of 60 mA/g ; (b) Capacity versus number of cycles of the full cell at different current densities[73]

图11 (a)使用HD-Zn和普通Zn片在5C倍率循环2圈后的循环伏安曲线和(b)5C倍率下HD-Zn和普通Zn片做负极时电池循环过程中的容量保持率[74]

Fig. 11 (a) Effect of HD Zn compared to Zn sheet as an anode on charge and discharge profiles of cycle 2 at 5C rate and (b) fractional capacity vs. cycle number compared for sheet Zn and HD Zn at 5C rate[74]

图12 (a) 在2 mV/s扫描速度下以0.5 mol/L的Na2SO4(1), 0.5 mol/L的K2SO4(2)和1 mol/L的ZnSO4(3)为电解液时锌离子电池的循环伏安曲线, (b) 不同倍率下锌离子电池的循环性能曲线[75]

Fig. 12 (a) CVs of ZnHCF in 0.5 mol/L Na2SO4 (1), 0.5 mol/ L K2SO4 (2), and 1 mol/L ZnSO4 (3) at scan rate of 2 mV/s ; (b) Cycle life tests at a rate of 1 C (square) and 5C (circle), 1C = 60 mA/g[75]

表1 单价离子和多价离子的电化学信息

Table 1 Detailed information of univalent and multivalent ions

Species	Diameter/nm	D/(×10^-4, m²·s)	ΔE/eV	Storage capacity /(mA h·g^-1)
Li⁺	0.069	13.8	-5.006	63
Na⁺	0.102	11.6	-4.493	68
K⁺	0.138	7.3	-5.601	53
Mg²⁺	0.066	22.8	-7.282	97
Ca²⁺	0.099	19.6	-2.092	99
Zn²⁺	0.074	8.6	-5.540	220
La³⁺	0.106	11.1	-10.019	101

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水系锌离子电池的研究进展

Research Progress and Prospect of Aqueous Zinc Ion Battery

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