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Triple-Layer Battery Resistant to Fire and Explosion Created

Researchers have developed a stable, efficient polymer-based solid electrolyte applicable to smartphones, EVs, and energy storage

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A research team from DGIST's (President Kunwoo Lee) Division of Energy & Environmental Technology, led by Principal Researcher Kim Jae-hyun, has developed a lithium metal battery using a "triple-layer solid polymer electrolyte" that offers greatly enhanced fire safety and an extended lifespan. This research holds promise for diverse applications, including in electric vehicles and large-scale energy storage systems.

Conventional solid polymer electrolyte batteries perform poorly due to structural limitations which hinder an optimal electrode contact.

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This could not eliminate the issue of "dendrites" either, where lithium grows in tree-like structures during repeated charging and discharging cycles.

Dendrites are a critical issue, as an irregular lithium growth can disrupt battery connections, potentially causing fires and explosions.

The research team, therefore, developed a triple-layer structure for the electrolyte to address such issues.

Each layer serves a distinct function, significantly enhancing the battery's safety and efficiency.

This electrolyte incorporates "decabromodiphenyl ethane (DBDPE)" to prevent fires, "zeolite" to enhance the electrolyte's strength, and a high concentration of a lithium salt, "lithium bis (trifluoromethanesulfonyl) imide) (LiTFSI)," to facilitate a rapid movement of lithium ions.

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The triple-layer solid electrolyte features a robust middle layer that boosts the battery's mechanical strength, while its soft outer surface ensures an excellent electrode contact, facilitating an easy movement of lithium ions.

This enables a faster movement of lithium ions, enhancing energy transfer rates and preventing dendrite formation effectively.

The experiment showed that the battery developed by the research team retained about 87.9% of its performance after 1,000 charging and discharging cycles, demonstrating a notable improvement in durability compared with traditional batteries, which typically maintain 70-80% of their performance.

It can also extinguish itself in a fire, thus significantly reducing the fire risk.

This battery is expected to be applicable across various sectors, ranging from small devices like smartphones and wearables to electric vehicles and large-scale energy storage systems.

Dr. Kim stated, "This research is anticipated to make a significant contribution to the commercialization of lithium metal batteries using [solid polymer] electrolytes, while providing enhanced stability and efficiency [to] energy storage devices."

This study was supported by the Future Materials Discovery Project (led by Professor Lee Jung-ho of Hanyang University) and the Mid-Career Researcher Program (led by Dr. Kim Jae-hyun) of the National Research Foundation of Korea. The findings were published as the cover article in an international academic journal, Small, published by Wiley.

-Note: This news release was originally published by DGIST (Daegu Gyeongbuk Institute of Science and Technology). As it has been republished, it may deviate from our style guide.

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