电解质
电池(电)
锌
离子
航程(航空)
大气温度范围
材料科学
对偶(语法数字)
无机化学
化学
冶金
热力学
复合材料
电极
物理
有机化学
物理化学
功率(物理)
艺术
文学类
作者
Zhiqiang Dai,Rungroj Chanajaree,Chengwu Yang,Xueqing Zhang,Xueqing Zhang,Manunya Okhawilai,Prasit Pattananuwat,Xinyu Zhang,Xinyu Zhang,Guanjie He,Jiaqian Qin
标识
DOI:10.34133/energymatadv.0139
摘要
Traditional aqueous electrolyte systems in zinc-ion batteries (ZIBs) often face challenges such as sluggish ion transfer kinetics, dendrite formation, and sudden battery failures in harsh temperature environments. Herein, we introduce a pioneering approach by integrating a bifunctional additive composed of ethylene glycol (EG) and sodium gluconate (Ga) into ZnSO 4 (ZSO) electrolyte to overcome these obstacles. The polyhydroxy structures of EG and Ga can reconstruct the hydrogen bond network of H 2 O to improve its liquid stability, and also adjust the coordination environment around hydrated Zn 2+ . Additionally, Ga in the H 2 O–EG mixture leads to the formation of a robust protective layer that promotes uniform deposition of Zn 2+ ions and minimizes unwanted side reactions. Therefore, Zn anodes with 40% ZSO–Ga electrolyte can cycle for more than 3,000 h at 25 °C and 800 h at 50 °C. Furthermore, Zn||NH 4 V 4 O 10 (NVO) full batteries demonstrate remarkable cycle stability, lasting up to 10,000 cycles at 1 A g −1 with a capacity retention of 79.1%. The multifunctional electrolyte additive employed in this study emerges as a promising candidate for enabling highly stable zinc anodes under diverse temperature conditions.
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