Engineering Energy Systems
for the Final Frontier—
Built for Space, Proven on Earth
When missions cost billions and failure isn't an option, you need technology engineered to survive where nothing else can. Our energy harvesting platform is being developed for lunar nights, Martian dust storms, and deep space radiation—and we're proving it works by deploying on Earth first.
Designed for Space. Validated on Earth.
We're engineering systems for the vacuum of space, radiation bombardment, and 300°C temperature swings—and proving our technology works by validating it on Earth first, where testing is faster and cheaper.
Designing for Space, Testing on Earth
Space missions demand perfection. But you don't validate in space first—you prove it works on Earth. We're building space-grade technology and demonstrating it commercially, reducing risk before launch while generating revenue.
Primary Focus: Space Missions
Extreme Environment Energy Systems
When space agencies plan decade-long missions to the Moon and Mars, power isn't a convenience—it's survival. Traditional systems fail. Batteries degrade. Solar panels lose efficiency. We're building the platform that won't.
Engineering for Mission Success:
• Designed to survive lunar night (-173°C) and solar day (+127°C)
• Radiation-hardened architecture for extended exposure
• Autonomous operation with no maintenance required
• No moving parts to break in vacuum
• Currently validating under simulated space conditions
Engaging with space agencies for lunar and Mars missions. Phase I validation proposal in development. Current TRL 3-4, targeting TRL 4-5 in 2026.
Commercial Application: Urban Fleets
Space-Grade Technology for Electric Vehicles
Why test space-grade technology on Earth first? Because real-world commercial validation proves reliability faster and cheaper than waiting years for space missions. We're demonstrating our systems work in high-volume deployments before putting them on billion-dollar spacecraft.
Space Engineering. Earth Economics:
• 40+ miles of daily charge-free driving
• $5,910+ annual savings per vehicle
• 50% reduction in charging downtime
• Space-grade durability for 10+ year lifespan
• Retrofit compatible with existing EV platforms
Early commercial deployment validates space technology while generating revenue. Pilot partnerships launching Q2-Q3 2026.
Space-Grade Design. Earth Validation. Future Space Heritage.
Commercial revenue today. Space missions tomorrow. Investors win twice.
Designed for Environments Where Failure Kills
Our platform isn't adapted from Earth systems—it's engineered from first principles for the harshest conditions in the universe. We're validating it commercially while advancing toward space qualification.
Radiation-Hardened Nano-Materials
When cosmic radiation destroys conventional electronics, we're engineering graphene and carbon nanotube composites designed to keep working. Built at the molecular level to survive everything space throws at them—from solar flares to galactic cosmic rays. Target temperature range: -173°C to +127°C. Target mission duration: 10+ years without degradation. This is materials science at its absolute limit.
Solid-State Piezoelectric Arrays
No moving parts. No lubrication. No maintenance. In space, mechanical systems are death sentences—they freeze, seize, and fail. Our piezoelectric arrays are designed to harvest energy from thermal cycles and vibrations with zero mechanical components. Target efficiency: 85%+. Target power overhead: under 1%. Built for missions where repair isn't an option and reliability must be measured in decades, not years.
Autonomous AI Control Systems
On Mars, light-speed delay means 20 minutes for a command to reach Earth and return. Our AI won't wait. It will monitor, adapt, and optimize autonomously—making split-second decisions to maximize energy harvest and prevent failures. Being trained on space mission data. Designed to harden against radiation-induced bit flips. Currently testing in simulated deep space conditions. This is intelligence you'll be able to trust when Earth is hours away.
Enabling the Next Era of Space Exploration
Artemis returns humans to the Moon. Mars Sample Return brings back evidence of life. Commercial stations orbit Earth. Every mission needs power systems that don't quit. That's where we come in.
Lunar Operations
Artemis Base Camp. Commercial landers. Sustained lunar presence. The Moon's 14-day night kills solar panels. Temperature swings of 300°C destroy batteries. Our systems are designed to harvest energy continuously and survive conditions that have ended missions for 50 years. Space agencies need this technology—we're working to deliver it.
Mars Surface Missions
Mars Sample Return. Human habitats. Long-duration rovers. Every Mars mission lives or dies on power availability. When dust covers panels and storms block sunlight, our energy harvesting is designed to continue. Temperature extremes, radiation exposure, and decade-long isolation? Exactly what we're engineering for.
Orbital Infrastructure
Commercial stations. Satellite constellations. Cislunar platforms. Low Earth Orbit will be the testbed for deep space. Our technology aims to prove reliability in LEO before deploying to lunar and Mars missions—building space heritage while generating revenue from commercial operators.
From Lab Validation to Mission Integration
Space qualification doesn't happen overnight. We are advancing through NASA's Technology Readiness Levels systematically—lab validation complete, system integration next, flight demonstration by 2027-2029.
Current: TRL 3-4
Component Validation Complete
Core technologies validated in laboratory environments:
• Thermal energy capture efficiency: 85%+
• Extreme temperature cycling: -173°C to +127°C
• Radiation exposure testing initiated
• Vacuum operation validated
• Materials characterization underway
• Power overhead confirmed under 1%
2026: TRL 4-5
Integrated System Validation
Q1: Space agency Phase I proposal submission
Q2: UC Berkeley partnership for materials testing
Q2: Prototype fabrication and integration
Q3: Thermal-vacuum chamber testing
Q4: Simulated space environment testing planned
Q4: Earth pilot deployment planned (pending partnerships)
2027-2029: Target TRL 6-7
Flight-Ready Development Path
Phase II space agency contracts (pending Phase I success)
Flight qualification testing
LEO demonstration mission (target)
Space heritage establishment
Lunar/Mars mission integration opportunities
Commercial space partnerships
Why Dual-Use Wins
Pure-play space companies bet everything on winning government contracts. We de-risk through dual markets—space validation proves our technology, Earth deployment funds our development.
Revenue Independence
Earth applications generate commercial revenue in 2026-2027. We don't wait for space agency budgets or contract awards. Fleet operators pay for technology that cuts their costs—funding our space development without diluting equity or begging for grants.
Accelerated Validation
Real-world Earth deployments validate system integration, manufacturing scalability, and long-term reliability—building credibility with space agencies faster than lab testing alone. Every commercial installation proves our technology works, reducing perceived risk for space missions.
Two Revenue Streams
Space: $150M-$450M TAM in mission-critical contracts ($2M-$7M per mission). Earth: $119B+ EV market with $5K-$8K retrofit kits. We don't choose between markets—we dominate both simultaneously. Investors get exposure to space innovation with commercial revenue protection.
Engineering the Future of Space Power
Whether you're planning missions to the Moon, operating satellites in LEO, or investing in space innovation—we have the technology space exploration has been waiting for.