氧化还原
级联
电池(电)
电解质
化学
纳米技术
电极
水溶液
铜
电化学
储能
化学工程
电压
伏特
铅酸蓄电池
工作(物理)
共晶体系
溶剂
材料科学
电阻器
化学稳定性
能量密度
作者
Lingchang Wu,Chaoyi Qiu,Junwei Zhang,Zihao Tao,Xin Liu,Zhixiao Cai,Haoxiang Yu,Lei Yan,Liyuan Zhang,Ting‐Feng Yi,Jie Shu
出处
期刊:Science Advances
[American Association for the Advancement of Science]
日期:2026-07-03
卷期号:12 (27): eaef2744-eaef2744
标识
DOI:10.1126/sciadv.aef2744
摘要
The quest for high-energy-density batteries has spurred interest in multielectron chemistry beyond conventional two-electron reactions. Here, we report a cascade battery that synergistically integrates gas-phase (Cl 2 ↔ Cl − ), liquid-phase (Cu 2+ ↔ Cu + ), and solid-phase (S ↔ CuS ↔ Cu 2 S) redox reactions within a deep eutectic solvent (DES) electrolyte. This unique gas-liquid-solid triphase coupling strategy unlocks a seven-electron transfer process. In particular, the chloride-rich DES electrolyte fundamentally alters the copper (Cu) redox thermodynamics, enabling a reversible liquid-phase Cu 2+ /Cu + couple via the formation of stable [CuCl 3 ] 2− complexes, which prevents disproportionation. The resulting cascade cell delivers an ultrahigh specific capacity of 4426.4 milliampere hours per gram [based on sulfur (S)] and exceptional cycling stability (88.5% capacity retention after 2000 cycles at 10 C). Furthermore, a practical pouch cell configuration achieves a high operating voltage of 1.5 volts and a remarkable energy density of 6917 watt-hours per kilogram (based on S; 2767 watt-hours per kilogram based on the total mass of the cathode), substantially surpassing most aqueous S-based systems. Ultimately, this work underscores that the strategic integration of orchestrated gas-liquid-solid triphase chemistry transcends the capacity limits of conventional single-phase reactions, demonstrating a viable pathway toward a next-generation paradigm for ultrahigh-energy-density storage.
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