Developing revolutionary Oxygen-Ion Batteries designed to thrive in extreme thermal environments.
Most energy storage technologies are developed for ambient conditions, then “protected” from heat. OxyBatt flips the approach: it is engineered for high temperature operation by design.
Powered by a breakthrough oxygen-ion chemistry, the battery is constructed using a fully solid, thin-film multilayer architecture. Relying on oxygen ions for energy storage is the fundamental enabler for extreme thermal stability — ensuring consistent behavior at temperatures that compromise conventional chemistries.
OxyBatt’s ambition is not only to
survive heat, but to enable operations where heat is unavoidable
Industrial hot zones
Gas turbines
Downhole drilling
Thermal extremes
1-10 μm
Thin-Film
architechure
Cell thickness in the micrometer scale
150-500°C
OPERATIONAL
TEMPERATURE
Designed for extreme
environments
3000+ cycle
Long cycle life
Healing cycle process
restores the capacity
350 mAh/cm³
Energy Density
High-performance storage
Flex
Form-Factor
Designed for conformable
integration
OxyBatt is created as a stack of functional layers, each optimized to work together at high temperatures. The thin-film approach enables tight control of thickness, interfaces, and materials—key for reliability in extreme environments.
High-temperature electronics are advancing, but power sources remain the missing link above ~200 °C. OxyBatt is designed to close this gap by delivering rechargeable power in environments where most batteries degrade rapidly.
Designed for maximum longevity, OxyBatt can actively restore its capacity to 100%. These built-in healing cycles prevent long-term degradation — drastically prolonging battery life and extending continuous operational uptime.
Powering sensors and actuators in high-heat manufacturing and processing lines without external cooling.
Sustained power for sealed turbine environments, thriving where heat is trapped and cooling is impossible.
Reliable energy storage for geothermal exploration and oil & gas extraction in extreme depth environments.
Survivable power systems for planetary missions with
extreme temperature swings and high radiation.
Follow the project’s progress, technology milestones, and field-facing developments. We share updates from lab
validation to industrial engagement, as well as international missions and events.
