Recent studies suggest that the lifespan of lithium-ion batteries can be extended using standard, cost-effective chemicals.

Lithium-ion batteries feature a porous separator sandwiched between a negative electrode and a positive electrode, immersed in an electrolyte that facilitates the movement of lithium ions during charging and discharging.

At the negative electrode, the electrolyte decomposes to create a thin protective coating that enhances battery stability and longevity.

Wang Chunsheng explains that forming a similar protective layer on the cathode has traditionally been challenging due to differing electrical conditions, which create a reactive environment that causes conventional electrolytes to break down before a stable coating can form, according to researchers from the University of Maryland.

Wang and his team utilized a straightforward reaction from organic chemistry to tackle this issue. This reaction enhances the electrolyte’s electron acceptance, inducing a controlled decomposition process that forms a stable protective coating on the cathode.

“By meticulously controlling the molecular decomposition of the electrolyte, we can precisely dictate the protective layer that forms on the cathode,” states Zhang Xiyue, a postdoctoral researcher in Wang’s group.

This flexibility in chemical reactions allows the resulting cathode-electrolyte layer to be tailored for enhanced protection, which could either provide strong shielding or design for faster electrochemical reactions, optimizing batteries for maximum power or extended life.

“If we can guarantee the formation of the cathode-electrolyte layer, it represents a significant advancement toward achieving longer battery cycles,” asserts Michel Armand from the CIC energiGUNE research center in Spain. Given that Wang and his colleagues modified the battery design using established chemical techniques, this new battery should be both safe and easy to manufacture, according to Armand.

While it remains uncertain exactly how much this innovative approach can extend the lifespan of lithium-ion batteries, further clarity is anticipated as the technology develops.

“This is a relatively simple modification to existing battery technology,” Wang notes. “After thorough safety and long-cycle testing, this approach could indeed reach consumers.”