ORNL Research Targets Larger, Safer Lithium-Ion Batteries
Given the current heightened interest in the safety of Lithium-ion (Li-ion) batteries in aerospace applications such as the Boeing 787, and looking toward improved batteries for electric cars and storing energy from renewable but intermittent solar and wind, scientists at Oak Ridge National Laboratory (ORNL) have announced the development of the first high-performance, nanostructured solid electrolyte for more energy-dense lithium ion batteries.
The ORNL team developed its solid electrolyte by manipulating a material called lithium thiophosphate so that it could conduct ions 1,000 times faster than its natural bulk form. The researchers used a chemical process called nanostructuring, which alters the structure of the crystals that make up the material.
"Think about it in terms of a big crystal of quartz vs. very-fine beach sand," said Adam Rondinone, coauthor of a newly published study in the Journal of the American Chemical Society. "You can have the same total volume of material, but it's broken up into very small particles that are packed together. It's made of the same atoms in roughly the same proportions, but at the nanoscale the structure is different. And now this solid material conducts lithium ions at a much greater rate than the original large crystal."
Today's lithium-ion batteries rely on a liquid electrolyte, the material that conducts ions between the negatively charged anode and positive cathode. But liquid electrolytes often entail safety issues because of their flammability, especially as researchers try to pack more energy in a smaller battery volume. Building batteries with a solid electrolyte, as ORNL researchers have demonstrated, could overcome these safety concerns and size constraints.
"To make a safer, lightweight battery, we need the design at the beginning to have safety in mind," said ORNL's Chengdu Liang, who led the development team. "We started with a conventional material that is highly stable in a battery system — in particular one that is compatible with a lithium metal anode."
The ability to use pure lithium metal as an anode could ultimately yield batteries five to 10 times more powerful than current versions, which employ carbon based anodes.
"Cycling highly reactive lithium metal in flammable organic electrolytes causes serious safety concerns," Liang said. "A solid electrolyte enables the lithium metal to cycle well, with highly enhanced safety."
The researchers are continuing to test lab scale battery cells, and a patent on the team's invention is pending.
"We use a room-temperature, solution-based reaction that we believe can be easily scaled up," Rondinone said. "It's an energy-efficient way to make large amounts of this material."