Quasi-solid battery combines safety and efficiency for electric vehicles and devices
Technological advances have led to the widespread use of electric devices and vehicles. These innovations are not only convenient but also environmentally friendly, offering an alternative to polluting fuel-driven machines.
Lithium ion batteries (LIBs) are widely used in electrical appliances and vehicles. Commercial LIBs comprise an organic electrolyte solution, which is considered indispensable to make them energy efficient. However, ensuring safety becomes a concern and may be difficult to achieve with the rising market demand.
While solid-state batteries can help mitigate safety issues, the interface between solid electrodes and the electrolyte is not conducive to optimum lithium-ion transfer. Moreover, the expansion and shrinkage of solid electrodes can disrupt the joint interface and hamper ion transfer. Therefore, there is a need to develop efficient solid-state batteries with a stable joint interface that can enhance their safety, utility, and performance.
To overcome these challenges, a team of researchers from Japan has developed a non-flammable quasi-solid-state LIB that can overcome the limitations of conventional batteries.
The study was led by Ryosuke Kido from Doshisha University and TDK Corporation, Japan, Professor Minoru Inaba and Professor Takayuki Doi from Doshisha University, and Atsushi Sano from TDK Corporation and their findings were published in the Journal of Energy Storage.
Giving further insight into their work, Mr. Kido the main author of the paper, says, “Increasing the capacity of positive and negative electrode active materials to achieve higher energy density reduces cycle performance and safety. The flame-retardant quasi-solid-state battery we developed, combining a liquid electrolyte and a solid electrolyte, provides a safer and more durable alternative to all-solid-state batteries with high energy density.”
The new battery design includes a silicon (Si) negative electrode and a LiNi0.8Co0.1Mn0.1O2 (NCM811) positive electrode, which are considered next-generation materials for LIBs.
These electrodes are separated by a solid lithium-ion conducting glass ceramic sheet (LICGC) from OHARA. To enhance compatibility and performance, the researchers developed non-flammable, nearly saturated electrolyte solutions tailored to each electrode.
The solutions used tris(2,2,2-trifluoroethyl) phosphate and methyl 2,2,2-trifluoroethyl carbonate, which were compatible with the electrodes and the solid electrolyte interface. The resulting 30 mAh-class quasi-solid-state pouch cells demonstrated excellent ionic conductivity, thermal stability, and electrochemical performance.
The researchers went on to assess the thermal stability and electrochemical performance of the quasi-solid-state LIB using electrochemical impedance spectroscopy, charge-discharge tests, and accelerating rate calorimetry (ARC).
Notably, the battery demonstrated high charge/discharge capacity with good cycle performance and little change in the internal resistance. Moreover, the ARC test revealed that the Si-LICGC-NCM811 structure with the respective electrolyte solutions showed improved thermal stability and that the heat generation associated with the side reaction was very low even in the high-temperature range of around 150°C.
Overall, the newly developed LIB has the potential to enhance the development of efficient and safer next-generation electric vehicles and cordless appliances like drones. Its widespread application can not only improve user convenience but also promote sustainable economic growth.
Mr. Kido concludes with the long-term implications of their work by saying, “As the world moves toward carbon neutrality, electric vehicles have been gaining significant attention in recent years.
“It is vital to develop highly safe automotive batteries with extended lifespans. The quasi-solid-state battery from our study has the potential to improve the longevity of liquid-based LIBs and enhance energy density while maintaining the safety of all-solid-state batteries.”
The study represents a step toward developing next-generation energy storage solutions that balance safety, efficiency, and environmental sustainability.
More information:
Ryosuke Kido et al, Highly safe quasi-solid-state lithium ion batteries with two kinds of nearly saturated and non-flammable electrolyte solutions, Journal of Energy Storage (2024). DOI: 10.1016/j.est.2024.114115
Doshisha University
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Quasi-solid battery combines safety and efficiency for electric vehicles and devices (2025, January 13)
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