Energy Applications (Batteries, Fuel Cells, Catalysis)
Where Atoms Power Energy’s Future
Energy Applications (Batteries, Fuel Cells, Catalysis)
The Smallest Scale Creates the Biggest Impact
Current energy storage and catalysis methods hit their ceiling because they can’t control matter at its most fundamental level. When you can’t precisely place atoms, you waste materials, create imperfect interfaces, and accept unnecessary performance limits.
Our atomic-layer approach gives you control at nature’s smallest building blocks—transforming how you design.
Materials That Matter for Energy’s Future
Battery Architecture Redefined
- Build protection layers measured in atoms
- not microns
- Craft interfaces where every molecule serves a purpose
- Establish concentration gradients that conventional methods can’t touch
- Create electrode structures that defy traditional manufacturing constraints
Catalysis Without Compromise
- Place active materials with atom-by-atom intentionality
- Stretch precious metals further than thought possible
- Run parallel experiments rather than sequential tests
- Build complex catalyst structures without wet chemistry headaches
From Lab Concept to Production Reality
- Work comfortably from ambient to 300°C
- Coat deep
- complex surfaces without thickness variation
- Dial in speeds from deliberate (0.1 mm/s) to rapid (100 mm/s)
- Scale your success without changing your fundamental approach
Your Atomic Toolkit for Energy Advancement
Power Generation Champions
- Platinum: Where hydrogen meets oxygen with unmatched efficiency
- Copper Oxide: Capturing energy where others can’t
- Iridium: The workhorse behind water-splitting technology
- Iridium Dioxide: Stable, resilient, and exceptionally active
- Niobium Oxide: The fast-charging specialist
Protection and Performance Enhancers
- Aluminum Oxide: The ultimate barrier against degradation
- Titanium Dioxide: Where stability meets functionality
- Zinc Oxide: Engineering interfaces at the atomic level
- Tin Oxide: Sensing and conducting with remarkable balance
- Vanadium Pentoxide: Storage capacity that exceeds expectations
Compatible With What You Already Use
- Silicon foundations
- Silicon Carbide power systems
- Gallium Nitride high-frequency components
- Glass enclosures
- Fused silica high-temperature elements
- Borosilicate laboratory equipment
- Polymer flexible substrates
Powering Tomorrow’s Energy Reality
- Electric Vehicles: Miles more range
- minutes less charging
- Aerospace: Maximum power
- minimum weight
- Consumer Electronics: The battery that finally keeps up
- Grid Storage: Decades of cycling
- not years
- Catalysis: Using atoms instead of particles
- efficiency instead of excess
Start Your Next Materials Breakthrough
Speak with our energy specialists about breaking your current material barriers.
