水溶液
阴极
锌
可扩展性
材料科学
低能
电池(电)
计算机科学
冶金
化学
功率(物理)
量子力学
数据库
物理
物理化学
原子物理学
作者
Gautam Ganapati Yadav,Malesa Sammy,Jung Sang Cho,Megan N. Booth,Michael Nyce,Jinchao Huang,Timothy N. Lambert,Damon E. Turney,Xia Wei,Sanjoy Banerjee
出处
期刊:Batteries
[Multidisciplinary Digital Publishing Institute]
日期:2025-08-01
卷期号:11 (8): 291-291
标识
DOI:10.3390/batteries11080291
摘要
Zinc (Zn)-based batteries have attracted significant interest for applications ranging from electric bikes to grid storage because of its advantageous properties like high abundance, non-toxicity and low-cost. Zn offers a high theoretical capacity of two electrons per atom, resulting in 820 mAh/g, making it a promising anode material for the development of highly energy dense batteries. However, the advancement of Zn-based battery systems is hindered by the limited availability of cathode materials that simultaneously offer high theoretical capacity, long-term cycling stability, and affordability. In this work, we present a new mixed material cathode system, comprising of a mixture of manganese dioxide (MnO2) and copper oxide (Cu2O) as active materials, that delivers a high theoretical capacity of ~280 mAh/g (MnO2 + Cu2O active material) (based on the combined mass of MnO2 and Cu2O) and supports stable cycling for >200 cycles at 1C. We further demonstrate the scalability of this novel cathode system by increasing the electrode size and capacity, highlighting its potential for practical and commercial applications.
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