A high-voltage rechargeable alkaline Zn-MnO4- battery with enhanced stability achieved by highly reversible MnO4-/MnO42- redox pair

Development of rechargeable alkaline Zn-Mn batteries has been facing big challenges for low working voltage and poor cycling stability, although they have advantages of low cost, high safety, and simple maintenance. For the first time, this work demonstrates a record high voltage (1.78 V) for rechargeable alkaline Zn-MnO4- battery achieved by a high reversible redox pair of MnO4-/MnO42-, which shows excellent cycling stability up to 1,500 cycles at a high current density of 20 mA cm(-2) without obvious capacity attenuation. The MnO4-/MnO42- redox reaction investigated by ex-situ scanning electron microscope as well as ultraviolet and visible absorption spectrum indicates high reversibility of the MnO4-/ MnO42- redox couple after the activation during the first discharge process. Furthermore, benefiting from the liquid-phase reaction nature of MnO4-/MnO42-, a flow battery is further prototyped to show highly stable cycles with 95.8% of discharge capacity retention for 600 cycles at the current density of 40 mA cm(-2). (C) 2021 Elsevier Ltd. All rights reserved.

Automated summary

This study demonstrates a record high voltage for rechargeable alkaline Zn-MnO4- battery achieved by a high reversible redox pair of MnO4-/MnO42-, showing excellent cycling stability. The redox reaction of MnO4-/MnO42- exhibits high reversibility and is further applied to a flow battery prototype with stable cycling performance.