溶剂化
电解质
离子液体
水溶液
三元运算
溶解度
电化学窗口
电离
电喷雾电离
电化学
化学物理
分子
盐(化学)
材料科学
电喷雾
化学
离子
工作(物理)
液态水
溶剂化壳
质谱法
强电解质
无机化学
溶解
同步加速器
散射
追踪
离子键合
分析化学(期刊)
化学工程
软物质
逆向蒙特卡罗
电池(电)
作者
Le Yu,S. J. Wang,Jing Huang,Xuanyu Zeng,Xiaoyan Zhou,Zhiqiang Wang,Junqing Chen,Jiliang Liu,Chaoji Chen
摘要
ABSTRACT Maximizing salt concentration to eliminate the active bulk-like water is the underlying logic of the ‘water-in-salt’ (WiS) strategy in advancing high-voltage aqueous battery chemistries, whereas salts with solubility capable of reaching the WiS regime (typically water-to-salt ratio < 5) are not commonplace. Here, we showcase that, by incorporating certain ionic liquids (ILs), any of the common Zn salts can be formulated into Zn electrolytes that fall into the WiS regime. As a proof-of-concept study, focusing on a ternary Wi(S/IL) system that features a large single-phase liquid region, we demonstrate that the complementary use of infrared/NMR/Raman spectroscopy, electrospray ionization mass spectrometry and synchrotron small-angle X-ray scattering succeed in precisely depicting how the local environment of H2O molecules, primary/secondary solvation sheaths of Zn2+, and other long-range molecular arrangements are structured. Further studies of electrochemical property, Zn cycling and electrolyte/Zn interphasial chemistry performed on a Wi(S/IL) electrolyte with optimal composition reveal that fully eliminating bulk-like water and constructing a weakly bonded anionic primary solvation sheath can promise a 4-V class electrolyte operation window and decent Zn plating/stripping reversibility of 99.7% over long-term cycling. This work implies a revolution of WiS strategy and, more importantly, a new paradigm for experimentally studying the liquid structures of aqueous electrolytes.
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