...However, the Li-metal anode is notoriously challenging

THE "SHARP" QUESTION

Conventional electrolytes are flammable and unstable against Li-metal, causing unfavored reactions that create sharp spikes called Li-dendrites, which damage the battery and pose safety hazards.

Dendritic Li-metal formed in the conventional electrolyte (Ref.)

THE "DULL" ANSWER

We create "new drug molecules" to treat the "diseases" of next generation batteries.

With years of meticulous R&D at Stanford University, we have proudly pioneered entirely new electrolyte molecules. These innovative molecules, distinct from any existing solutions, demonstrate superior stability with Li-metal, even under high-temp. They passivate Li-metal surface and eradicate Li-dendrites, ushering in a new era of battery technology that promises unparalleled safety, extended lifespan, and increased energy density.

Feon Li-metal anode shows zero dendrite after extensive cycling

LI-METAL BATTERY WITH ZERO DENDRITE

...However, the Li-metal anode is notoriously challenging

THE "SHARP" QUESTION

Dendritic Li-metal formed in the conventional electrolyte (Ref.)

THE "DULL" ANSWER

Feon Li-metal anode shows zero dendrite after extensive cycling

LI-METAL BATTERY WITH ZERO DENDRITE