Peng Zhang , Weili Zhang , Zhengjie Wang , Xuefei Wang , Qingjuan Ren , Shuai Zhang , Yujia Wang , Liang He , Pan Liu , Qingyin Zhang , Zhiqiang Shi
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引用次数: 0
摘要
水溶液电解质为先进的能量存储提供了良好的前景。“盐中水”(WIS)电解质具有较宽的电化学稳定性窗口(ESW),但其低电导率、高粘度和低温下的沉淀限制了其应用。在此,我们报道了一种新的局部“吡咯吡啶水”电解质(LWIP;1 mol/L, N-丙基-N-甲基吡咯吡啶氯化铵/(水和N,N-二甲基甲酰胺,质量摩尔浓度1:4)),使高压,低温超级电容器(SCs)。显著提高的ESW (3.451 V)主要是由于Cl−与水分子之间的强溶剂化作用,扩大了负稳定性。这种水结合机制与基于碱金属盐的WIS电解质的水结合机制有很大不同。使用LWIP电解质的SCs不仅可以产生2.4 V的高工作电压和出色的容量保持率(在5 ag - 1下循环15,000次后容量保持率为82.8%),而且还可以在- 20°C下稳定工作。这项工作为新型电解质的设计和制备提供了新的途径。
High-voltage, low-temperature supercapacitors enabled by localized “water-in-pyrrolidinium chloride” electrolyte
Aqueous electrolytes offer superior prospects for advanced energy storage. “Water-in-salt” (WIS) electrolytes exhibit a wide electrochemical stability window (ESW), but their low conductivity, high viscosity, and precipitation at low temperatures restrict their application. Herein, we report a novel localized “water-in-pyrrolidinium chloride” electrolyte (LWIP; 1 mol/L, N-propyl-N-methylpyrrolidinium chloride/(water and N,N-dimethylformamide, 1:4 by molality)) enabling high-voltage, low-temperature supercapacitors (SCs). The greatly improved ESW (3.451 V) is mainly attributed to the strong solvation between Cl− and water molecules, which broadens the negative stability. This water-binding mechanism is very different from that of a WIS electrolyte based on alkali metal salt. SCs using LWIP electrolytes not only yield a high operating voltage of 2.4 V and excellent capacity retention (82.8% after 15,000 cycles at 5 A g−1) but also operate stably at −20 °C. This work provides new approaches for the design and preparation of novel electrolytes.
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