Asadi aimed to make a battery with a solid electrolyte, which provides safety and energy benefits compared to liquid electrolyte batteries, and sought an option that would be compatible with the cathode and anode technologies that he has been developing for use in lithium-air batteries. He chose a mix of polymer and ceramic, which are the two most common solid electrolytes but both of which have downsides. By combining them, Asadi found that he could take advantage of ceramic’s high ionic conductivity and the high stability and high interfacial connection of the polymer.

The result allows for the critical reversible reaction that enables the battery to function — lithium-dioxide formation and decomposition — to occur at high rates at room temperature, the first demonstration of this in a lithium-air battery.

As described in the Science paper, Asadi has conducted a range of experiments that demonstrate the science behind how this reaction occurs.

“We found that that solid-state electrolyte contributes around 75% of the total energy density,” said Asadi. “That tells us there is a lot of room for improvement because we believe we can minimize that thickness without compromising performance, and that would allow us to achieve a very, very high energy density.”

These experiments were conducted in collaboration with University of Illinois Chicago and Argonne National Laboratory. Asadi says he plans to work with industry partners as he now moves toward optimizing the battery design and engineering it for manufacturing.   

“The technology is a breakthrough, and it has opened up a big window of possibility for taking these technologies to the market,” said Asadi.

Disclaimer: Research reported in this publication was supported by the U.S. Department of Energy under Award Number DE-AC02-06CH11357. This content is solely the responsibility of the authors and does not necessarily represent the official views of the U.S. Department of Energy.