Soft, solid battery electrolyte could see EVs go great distances

Lithium metal batteries, in which the graphite material in the anode is swapped out for pure lithium metal, could be a game changer when it comes to energy storage, potentially offering far greater capacity and an ability to charge much faster. Scientists are reporting a new breakthrough in this area, demonstrating how an electrolyte made of soft and solid materials can prevent the formation of tree-like growths that normally prove fatal to the battery’s performance.

The reason lithium metal batteries are seen as such a promising technology in energy research circles is that pure lithium metal offers excellent energy density. This means they could offer as much as 10 times the capacity of today’s batteries, and possibly charge in just a fraction of the time.

One of the major roadblocks standing in the way, however, are troublesome, tentacle-like protrusions called dendrites. These form on the surface of the graphite anode as the battery charges and ultimately cause it to short-circuit, fail or catch fire. A lot of the focus in battery research centers on suppressing these growths, and we’ve seen a few promising solutions of late.

These have included incorporating protective layers into the anode to prevent dendrite growth, using scaffolds made of carbon nanotubes for the same effect, and even bringing adhesive tape into the mix.

The team behind the latest breakthrough, made up of scientists from the Lawrence Berkeley National Laboratory and Carnegie Mellon University, see the solution in a new class of soft, solid electrolytes. The electrolyte is the material that facilitates the movement of ions back and forth between the cathode and anode, and the team believes it may have come up with just the right recipe for use in lithium metal batteries.

The material consists of soft, porous polymers, with the tiny holes packed with nanoscale ceramic particles. This combination of soft and solid materials was put to the test in the lab, with the team using X-ray imaging to observe the interactions between lithium metal anode and electrolyte during up to 16 hours of operation.