Researchers led by Prof. HU Linhua from the Hefei Institutes of Physical Science of the Chinese Academy of Sciences and Prof. JI Denghui from Shijiazhuang University have recently developed a hydrogel electrolyte, which endows batteries with better stability in wider temperature range (-20 °C to 60 °C), more flexible device application, and larger capacity.
The related research was published in Chemical Engineering Journal.
Aqueous zinc-ion batteries are considered as potential alternatives for conventional lithium-ion batteries due to their abundant resources and improved safety. Hydrogel electrolyte used in zinc-ion batteries helps improve their safety against fire and leakage compared with conventional lithium-ion batteries. But there are still some problems such as poor stability and performance under extreme conditions.
Temperature window is a key problem of electrolyte in battery. To address this problem, the joint team developed a hydrogel electrolyte by in situ copolymerization of acrylamide (AM) and N,N '-methylene bisacrylamide (MBA) in the mixture of water, glycerin, acetonitrile, and zinc sulfate. The copolymer of acrylamide and N,N '-methylene diacrylamide is the 3D framework of hydrogel electrolyte, and zinc salt is the zinc source.
The copolymer increased the proportion of intermolecular hydrogen bond between copolymer and water molecule, but decreased the proportion of intramolecular hydrogen bond between water molecule. The bonding interaction regulation can reduce the chance of freezing at low temperature and evaporation at high temperature, which is beneficial to expand the operating temperature range.
Another advantage of this hydrogel electrolyte is its good mechanical properties for flexible device applications. In this study, the scientists found that the voltage of the zinc-ion battery device remained constant after it was bent at different angles.
In addition, the electrochemical performance of the hydrogel electrolyte at 5 A·g-1 is 185 mAh·g-1. In Zn//Zn battery, the capacity retention rate of 10,000 cycles is 88%, and the cycle stability of 3,000 cycles is improved.
This strategy provides a new idea for the design of functional electrolyte of aqueous zinc ion batteries.