We're building the first commercially viable compact fusion reactor. Smaller, safer, and scalable by 2030.
Why the dream of limitless energy has remained 20 years away for the last 50 years.
Tokamaks require massive infrastructure the size of stadiums. The sheer capital intensity makes rapid iteration impossible.
Confining superheated plasma for sustained periods requires complex magnets that consume more energy than the reaction creates.
Even if they work, the cost per kilowatt-hour of traditional fusion plants would likely exceed solar and wind by 10x.
By utilizing next-generation high-temperature superconductors (HTS), we can create stronger magnetic fields in a device 1/50th the size.
Factory-built modules that can be shipped by truck, not built on-site.
Development cycles in months, not decades. Real-world data, faster.
We are currently in Phase 2 of our deployment strategy.
Validated physics model and magnetic containment stability.
Construction of "Spark-1", our first net-energy capable reactor.
Grid connection and sustained power delivery test.
Global deployment of modular fusion units.