Nanostructured-Carbon-Based Materials Using Mantel Peridocarbon Mineralization Based Activated Carbon Nanotubes™, a newly patented technology available for licensing. The global carbon nanotube (CNT) market has witnessed exponential growth over the past decade, driven by demand for advanced materials that deliver superior strength, conductivity, and multifunctionality in industries ranging from energy storage to aerospace. Key factors fueling this expansion include the rise of electric vehicles that rely on high‑performance batteries, the push for lightweight composites in aviation, and the need for next‑generation electronics with faster, smaller, and more efficient components. However, conventional carbon nanotube production often depends on expensive catalysts, like platinum, or hazardous chemicals, limiting widespread adoption and driving up costs.

Nanostructured-Carbon-Based Materials Using Mantel Peridocarbon Mineralization Based Activated Carbon Nanotubes™ revolutionizes the nanostructured carbon‑base materials landscape by delivering an optimal balance of economics, conductivity, mechanical strength, and environmental stewardship. Harnessing an innovative carbon‑sequestration feedstock with peridotite rock, Nanostructured-Carbon-Based Materials Using Mantel Peridocarbon Mineralization Based Activated Carbon Nanotubes™ captures atmospheric carbon dioxide, converts it into activated carbon, and then transforms that natural carbon into nitrogen‑doped carbon nanotubes without resorting to using precious metals or toxic reagents. The result is a turnkey solution for manufacturers seeking cost‑effective, high‑performance carbon nanotubes that outperform traditional copper, aluminum, and platinum‑based alternatives.

 

 

 

 

 

PRODUCT FEATURES & BENEFITS

 

Special Features

• Revolutionizes the nanostructured carbon-base material industry by balancing economics, conductivity, strength, and environmental stewardship.

• Uses naturally abundant, magnesium and calcium rich peridotite rock that, when ground and melted into glass cells, captures carbon dioxide from air to form activated carbon precursor.
• Has carbon dioxide‑sequestration process where glass cells formed from peridotite actively mineralize atmospheric carbon dioxide during weathering, turning an air‑pollution treatment byproduct into natural carbon.
• Processes activated, mineralized carbon into nitrogen‑doped carbon nanotubes without requiring precious metals or toxic nanofabrication steps.
• Functions as an economical alternative to platinum catalysts in lithium‑air batteries and fuel cells, achieving comparable catalytic performance by being a non-precious metal catalyst.
• Has high electrical conductivity with carbon nanotube conductors that exhibit metallic/semiconductive behavior, enabling them to replace copper or aluminum wiring in electronics.
• Mechanically robust design suitable for structural composites by being lightweight, slim, strong, and corrosion‑resistant.
• Versatile, low-cost electrode material that can be used in fuel cells and as anodes in lithium-ion batteries.
• Able to use as a composite reinforcement where it can be embedded in epoxy for stiffer, stronger wind‑turbine blades or aircraft components.
• Capable to be integrated with printable carbon nanotube‑based inks and flexible carbon wires for printed electronics.
• Enables metal‑replacement in sports equipment (bats and clubs), automotive and aircraft panels, reinforced plastics, fabrics, tapes, and sleeves.
• Can use with various microelectronics applications such as carbon nanotubes in computer chips (wiring and transistors) and in lightweight mirror structures for CubeSat telescopes.
• Integrates carbon dioxide capture with carbon nanotube production, turning a greenhouse‑gas mitigation step into valuable advanced‑material feedstock with a scalable manufacturing process.
• Straightforward manufacturing process to create and integrate with products

 

 

 

PRODUCT DETAILS

Nanostructured-Carbon-Based Materials Using Mantel Peridocarbon Mineralization Based Activated Carbon Nanotubes™ harnesses the natural weathering of magnesium and calcium rich peridotite rock, which is an abundant silicate from Earth’s upper mantle. This patented process captures and mineralizes atmospheric carbon dioxide into activated carbon. This mantle‑mineralized carbon is then transformed into nitrogen‑doped carbon nanotubes via a straightforward chemical vapor deposition (CVD) process, yielding a non‑precious‑metal catalyst that matches the performance of platinum in batteries and fuel cells. The result is an affordable, high‑conductivity, lightweight material that unlocks economical lithium‑air batteries for electric vehicles and a host of other applications from reinforced composites to next‑generation electronics and medical devices without the cost or complexity of traditional precious‑metal catalysts.

 

At the heart of Nanostructured-Carbon-Based Materials Using Mantel Peridocarbon Mineralization Based Activated Carbon Nanotubes™ is a patented process that begins with abundant peridotite rock. When ground and melted into specialized glass cells, the peridotite actively mineralizes carbon dioxide from ambient air, turning an environmental liability into a valuable precursor. This integrated carbon dioxide‑sequestration step not only reduces greenhouse gas concentrations, but it also yields an activated carbon feedstock that is inherently more sustainable than fossil‑derived alternatives. By embedding carbon capture directly into the materials supply chain, Nanostructured-Carbon-Based Materials Using Mantel Peridocarbon Mineralization Based Activated Carbon Nanotubes™ offers manufacturers a performance edge to integrate in their products while also being good environmental stewards.

Traditional carbon nanotube (CNT) production relies on expensive catalysts like platinum or involves toxic chemical steps that raise both costs and safety concerns. Nanostructured-Carbon-Based Materials Using Mantel Peridocarbon Mineralization Based Activated Carbon Nanotubes™ fluidized‑bed CVD process sidesteps these issues entirely where the mineralized peridotite carbon is doped with nitrogen and converted into multi‑walled CNTs with exceptional purity and consistency. It accomplishes all of this without a single gram of precious metal. The resulting nitrogen‑doped CNTs deliver catalytic performance on par with platinum in lithium‑air batteries and fuel cells, enabling device makers to reduce material costs by up to 80% while maintaining or improving energy density and cycle life.

Nanostructured-Carbon-Based Materials Using Mantel Peridocarbon Mineralization Based Activated Carbon Nanotubes™ exhibit metallic to semiconductive electrical behavior, making them ideal replacements for copper or aluminum wiring in advanced electronics, flexible circuits, and printed‑ink applications. Their high aspect ratio and nitrogen‑doping confer exceptional conductivity while maintaining a low material weight. Mechanically, the CNTs are slim yet robust, with tensile strengths surpassing steel at a fraction of the density, and inherent corrosion resistance that ensures long‑term reliability in harsh environments. Whether reinforcing wind‑turbine blades through epoxy composites or forming the backbone of next‑generation wearable sensors, Nanostructured-Carbon-Based Materials Using Mantel Peridocarbon Mineralization Based Activated Carbon Nanotubes™ delivers unmatched performance per gram.

From low‑cost electrodes in lithium‑ion batteries and fuel cells to metal‑replacement in sports equipment, automotive panels, and aerospace structures, Nanostructured-Carbon-Based Materials Using Mantel Peridocarbon Mineralization Based Activated Carbon Nanotubes™ excel wherever conductivity, strength, and weight savings are needed. Printable CNT‑based inks and flexible carbon wires open the door to roll‑to‑roll printed electronics, RFID tags, and conformal sensors. In microelectronics, Nanostructured-Carbon-Based Materials Using Mantel Peridocarbon Mineralization Based Activated Carbon Nanotubes™ supports both interconnect wiring and transistor channels. It can even be used in lightweight mirror coatings for CubeSat telescopes. Best of all, the entire manufacturing workflow from peridotite grinding and carbon dioxide capture to CVD synthesis is designed for scale, with straightforward equipment requirements and low operational complexity. This ensures that Nanostructured-Carbon-Based Materials Using Mantel Peridocarbon Mineralization Based Activated Carbon Nanotubes™ can be adopted rapidly by existing materials producers, delivering high margins and green credentials in equal measure.

Materials needed to produce Nanostructured-Carbon-Based Materials Using Mantel Peridocarbon Mineralization Based Activated Carbon Nanotubes™:

• Peridotite rocks
• Stone grinder
• Kiln burner
• Molds
• Display glass panel
• Fluidized bed CVD

 

The Nanostructured-Carbon-Based Materials Using Mantel Peridocarbon Mineralization Based Activated Carbon Nanotubes™ is covered by United States Utility Patent: 11,591,220

 

For additional information, licensing opportunities, and a full prospectus on the Nanostructured-Carbon-Based Materials Using Mantel Peridocarbon Mineralization Based Activated Carbon Nanotubes™ contact:

 

 

BankOnIP

VP of Business Development

Email: info@BankOnIP.com