Alex Bates (left) and John Hewson (right) examine a lithium-ion battery in front of a specially designed battery testing chamber. Photo: Rebecca Gustaf/Sandia National Laboratories.
Alex Bates (left) and John Hewson (right) examine a lithium-ion battery in front of a specially designed battery testing chamber. Photo: Rebecca Gustaf/Sandia National Laboratories.

Solid-state batteries, currently used in small electronic devices like smart watches, have the potential to be safer and more powerful than lithium-ion batteries for things such as electric cars and storing energy from solar panels for later use. However, several technical challenges remain to be resolved before solid-state batteries can become widespread.

A study led by researchers at the Sandia National Laboratories has now tackled one of these challenges – a long-held assumption that adding some liquid electrolyte to improve performance would make solid-state batteries unsafe. Instead, the research team found that in many cases solid-state batteries with a little liquid electrolyte were safer than their lithium-ion counterparts. They also found that if the battery were to short-circuit, releasing all its stored energy, the theoretically super-safe, all-solid-state battery could put out a dangerous amount of heat. The researchers report their findings in a paper in Joule.

“Solid-state batteries have the potential to be safer, and they have the potential for higher energy density,” said Alex Bates, a Sandia postdoctoral researcher who led the study. “This means, for electric vehicles, you could go farther in between charges, or need fewer batteries for grid-scale energy storage. The addition of liquid electrolyte may help bridge the gap to commercialization, without sacrificing safety.”

Solid-state batteries are somewhat like lithium-ion batteries. In both, lithium ions move from one side of the battery to the other, driving electrons through a circuit to power a device. One big difference is that in a lithium-ion battery the lithium ions move through a liquid electrolyte.

Loraine Torres-Castro, a battery safety expert in Sandia’s Battery Abuse Testing Laboratory who was involved in the project, compares a liquid electrolyte to a fleet of cars pulling into driveways: it shuttles lithium ions directly where they need to go. But current liquid electrolytes are flammable and can cause batteries to catch fire or even explode, especially when the battery is damaged.

In a solid-state battery, the liquid electrolyte is replaced by a solid material known as a solid electrolyte that also helps the lithium ions move quickly. One technical challenge is that while the lithium ions can move quickly within the solid electrolyte, they have a hard time moving from the solid electrolyte to the electrodes and vice versa. The solid electrolyte can be compared to a cadre of trains, also quickly shuttling the lithium ions to the station, but then the passengers still have to travel a bit farther to get home.

One way that scientists have managed to speed up this ‘direct shuttling’ – and thus battery charging speeds and performance – is by adding a little bit of liquid electrolyte to the positive side of the battery. But this has raised concerns.

“There has been a lot of controversy in the solid-state battery research community about the safety of including liquid electrolyte to ‘grease the wheels’,” said Yuliya Preger, a Sandia battery reliability expert on the project. “Some scientists say that any amount of liquid electrolyte is unsafe. So, we did the calculations to see what the impacts of liquid electrolyte could be, instead of just accepting the ‘party line’.”

Steve Harris, a battery scientist at Lawrence Berkeley National Laboratory, and Katie Harrison, a Sandia battery scientist, first questioned the ‘party line’ that led to the study, which they were both involved in.

In order to figure out just how safe a solid-state battery with a little liquid electrolyte would be, the research team started by calculating how much heat could be released by a lithium-ion battery, an all solid-state battery and solid-state batteries with varying amounts of liquid electrolyte. All batteries tested had equivalent amounts of stored energy. Then the researchers looked at three different bad things that could happen to the batteries, and the heat that would be released due to each type of failure.

“We started by determining just how much chemical energy is in the three kinds of batteries,” said John Hewson, a Sandia heat-release calculation expert on the project. “There’s only so much energy you can release, which will heat up the battery a certain amount, if a chemical reaction does occur.”

The first bad thing that could happen is if the batteries caught fire – from either a neighboring battery or a surrounding building. In these cases, the researchers found that the solid-state battery with a little liquid electrolyte in it produced about one-fifth of the heat of a comparable lithium-ion battery — depending on how much liquid electrolyte it had. The solid-state battery without liquid electrolyte didn’t produce any heat under this scenario.

The second bad thing that could happen to the batteries is if repeated charging and discharging caused the lithium metal to form a ‘spike’ called a dendrite. This dendrite can puncture a hole through the separator that keeps the two sides of the battery distinct, causing a short-circuit. This is a known issue with all batteries that have lithium metal on one side. In this case, all three batteries produced similar amounts of heat, which depended on how much lithium metal was in the batteries.

The third bad thing that could happen to a solid-state battery is the solid electrolyte could break. This could happen if the battery was crushed or punctured or due to a build-up of pressure during operation, which would allow oxygen from one side of the battery to react with the lithium metal on the other side. In these cases, the solid-state battery without liquid electrolyte could reach temperatures near that of the lithium-ion battery, which the team found surprising.

“One of the promises of solid-state batteries is that they are safe because the solid electrolyte is firm and unlikely to break. But if it does break, the temperature rise could be about as much as when lithium-ion batteries fail,” Preger said. “This study highlighted the importance of engineering the heck out of that separator so that it does not fail.”

The next steps for the project include conducting similar calculations with other solid electrolyte materials and conducting experiments to validate the new and original calculations.

“We found if the solid-state battery has lithium metal, it has the potential to be dangerous, regardless of if it has liquid electrolyte or not,” Bates said. “What we were trying to point out in this paper is that there’s a definite trade-off between performance and safety, but adding a bit of liquid may greatly increase performance while only having a small impact on safety.”

Understanding this trade-off may help speed up commercialization, Torres-Castro added. “Having the clarity and the confidence that knowing a small amount of liquid electrolyte will not create huge safety issues may help the development of commercial solid-state batteries. Adding liquid electrolyte could fix one of their main problems, the solid-electrolyte interface.”

This story is adapted from material from Sandia National Laboratories, with editorial changes made by Materials Today. The views expressed in this article do not necessarily represent those of Elsevier. Link to original source.