01 β Graphite Separation
Revolutionizing Graphite Production with Dry Separation Technology
Extracting High-Purity Large Flake Graphite for Critical Industries
πΏ
99% Lower Emissions – than traditional flotation processing.
π§
Zero Water Usage – no waste, no contamination.
βοΈ
No Harmful Chemicals – completely environmentally benign.
β‘
Faster Time-to-Market – high-efficiency, dry processing.
π°
Cost-Competitive Globally – low cost production, lower CAPEX.
π¬
98.5% Purity – verified by third-party testing.
“By maintaining crystallinity, we improve recovery,
reduce downstream processing requirements,
and enable higher-value outputs across multiple markets.”
Pathways Enabled
β Battery materials
β Expandable graphite
β Graphene and advanced carbon materials
02 β Battery Initiative
Lithium Metal Architecture Designed for the Real World
Solid UltraBattery is building the next generation of lithium metal batteries at our facility in Guelph, Ontario. Our electrolyte-driven platform delivers higher energy density, stable temperature performance, and proven cycle life with working pouch cells already developed.
Why It Wins
Higher Energy Density – 300β400+ Wh/kg pathway. Available in 260 Wh/kg and 400 Wh/kg pouch cell variants.
Stable Across Temperature Extremes – maintains performance where conventional lithium-ion degrades.
Improved Cycle Life – clear trajectory toward 1,000+ cycle commercialization target.
Platform Approach – designed for EV, robotics, aerospace, and defense. Scalable architecture.
Current Laboratory Test Results
650
Cycles @ 94.9% Retention – BMLMP / Li-metal
1,100
Cycles @ 80% Retention – LFP / Li-metal
1,600
Cycles @ 80% Retention – NMC811 / Li-metal
1,000+
Cycle Commercialization Target – proven path to commercialization.
Deploys In
π Electric Vehicles
βοΈ Aerospace
π€ Robotics
π‘οΈ Defense
03 β Critical Minerals & Rare Earth Assets
Mount Copeland REE, Molybdenum and Rhenium Advancement
Mount Copeland hosts a multi-commodity critical minerals system with rare earth elements, niobium, molybdenum, and rhenium. Volt Carbon is developing robotic, AI-driven dry separation to upgrade mineralized material β without water or chemical processing.
REE Mineralization
Historic data reports La ~10%, Ce ~13.1%, and Pr ~0.77%. Recalculated results indicate approximately 26% TREO from sample COPE10AR-20.
Rhenium Recovery
Initial work produced molybdenum concentrates with rhenium values up to ~2,790 ppm as measured internally by XRF. Rhenium occurs at 0.7 ppb in Earth’s crust β a critical input in aerospace and defense superalloys.
Processing Method
Robotic, AI-driven dry separation upgrades mineralized material without water or chemical processing β positioning Mount Copeland as a scalable, technology-enabled critical minerals opportunity.
Domestic Supply Chain
This combination of high-value materials and scalable processing aligns with domestic and secure North American critical mineral supply chain priorities.
All values are based on selective and historical data and may not be representative. Independent verification is in progress.
