ProLogium celebrates its 20th anniversary by introducing its proprietary Superfluidized All-Inorganic Solid-State Lithium Ceramic Battery at CES 2026. This breakthrough platform combines a superfluidized all-inorganic solid electrolyte, an all-ceramic separator, and an all-silicon anode, delivering unmatched energy density, safety, and manufacturability. ProLogium plans to expand production to EVs, construction machinery, humanoid robots, e-bikes, and energy storage systems.
How Does ProLogium’s Superfluidized Battery Work?
The battery architecture eliminates flammable liquid electrolytes and prevents thermal runaway through:
All-inorganic electrolyte: Non-flammable, safe under extreme temperatures and stresses.
All-ceramic separator: Prevents direct contact between anode and cathode.
Active Safety Mechanism (ASM): Converts unstable materials to stable crystalline structures under high-risk conditions.
Performance highlights include:
Volumetric energy density: 860 Wh/L
Ionic conductivity: 57 mS/cm (≈5× higher than conventional liquid or sulfide solid electrolytes)
Low-temperature performance equal to room-temperature operation
Rapid charging: 4–6 minutes for 60–80% capacity
What Applications Are Targeted?
ProLogium’s platform is versatile, supporting:
Electric vehicles and e-bikes
Construction machinery and industrial equipment
Humanoid robots and drones
AI data center energy storage systems (ESS)
Marine and aerospace applications
The battery’s design allows ultra-lightweight, high-throughput, and safe configurations for diverse mobility and industrial solutions.
What Is the France Gigafactory Timeline?
ProLogium plans a European production base in Dunkirk, France, to serve the growing solid-state battery market:
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2026: Official groundbreaking and construction start
2028: Phase 1 completed; mass production of Gen4 batteries (0.8 GWh) begins
2030: Phase 2 completed; full operation at 4 GWh
2032: Phase 2 completion; total capacity reaches 12 GWh
Future expansion: up to 48 GWh in line with global demand
The Dunkirk facility leverages local low-carbon energy and port logistics for efficient production and supply chain resilience.
How Does ProLogium Compare to Other Solid-State Batteries?
| Feature | ProLogium Superfluidized | Conventional Solid-State |
|---|---|---|
| Energy Density | 860 Wh/L | 400–500 Wh/L |
| Charge Time | 4–6 min (60–80%) | 10–15 min |
| Ionic Conductivity | 57 mS/cm | 10–12 mS/cm |
| Safety | No thermal runaway | Risk of dendrites or overheating |
| Low-Temp Performance | Full capacity | Reduced performance |
| Scalability | High manufacturability | Limited |
Founder & CEO Statement
Vincent Yang emphasizes: “Solid-state batteries should not remain in labs. Our modules and system-level results showcase safer, higher-energy, and environmentally adaptive technologies ready for mass production and deployment in EVs, industrial machinery, robotics, and energy storage. Our France gigafactory ensures local supply, faster market access, and a resilient supply chain.”
Future Outlook
ProLogium’s technology expands the solid-state battery market beyond EVs to industrial, mobility, and AI energy storage applications. With mass-production-ready modules and unparalleled safety, the Superfluidized All-Inorganic platform positions ProLogium at the forefront of next-generation energy solutions.
