Graphene Carbon Nanotubes / CNTs Doped with 30wt% Graphene Nanopowder
Graphene Carbon Nanotubes | |
Product No | NRE-37011 |
CAS | NA |
Purity | 97% |
Average Diameter | >55 nm |
Average Length | 10-30umm (TEM) |
Special Surface Area(SSA) | 60 m2/g (BET) |
Tap Density | 0.12 g/cm3 |
True Density | 2.1 g/cm3 |
Electric Conductivity | > 100 S/cm |
Thermal Conductivity | NA |
Graphene Carbon Nanotubes
Graphene carbon nanotubes (G-CNTs) are advanced nanomaterials that merge the exceptional properties of graphene with those of carbon nanotubes (CNTs). Graphene is a single layer of carbon atoms arranged in a two-dimensional hexagonal lattice, celebrated for its outstanding electrical conductivity, thermal conductivity, and mechanical strength. Carbon nanotubes, which are cylindrical structures made from rolled-up sheets of graphene, are known for their remarkable tensile strength, flexibility, and unique electronic properties.
Potential Applications:
Applications of Carbon Nanotubes
Electronics
Screen Displays: Used in flat-panel displays for improved conductivity and flexibility.
Electric Motors: Enhance performance and efficiency through improved electrical properties.
Sensing Devices: High sensitivity for gas sensors and biosensors, detecting various substances.
Electron Field Emitters: Utilized in cathode ray lighting elements for better electron emission.
Aerospace and Automotive
Lightweight Components: Reinforcements in composites for improved strength-to-weight ratio.
Energy Conversion: Used in fuel cells and batteries, such as lithium battery anodes.
Electromagnetic-Wave Absorption and Shielding: Protects sensitive electronic components from interference.
Textiles and Protective Gear
Body Armor: Incorporation into fabrics for enhanced protective properties.
Tear-Resistant Cloth Fibers: Provides durability and strength in textiles for various applications.
Sports Equipment: Used in gear for improved performance and safety.
Coatings and Films
Conductive Films: Applied in coatings for plastics and other materials to enhance conductivity.
Additives in Polymers: Improves mechanical and electrical properties of composite materials.
Energy and Storage
Hydrogen Storage: CNTs can absorb hydrogen gas, making them suitable for fuel storage.
Supercapacitors: High surface area improves energy storage capabilities.
Catalysis and Chemical Applications
Catalysts: Enhance reaction rates in various industrial processes.
Nanoelectrodes: Used in nanolithography for precision applications.
Biomedical Applications
Drug Delivery: CNTs serve as carriers for targeted and controlled drug release.
Nanoprobes for STM, AFM, and EFM Tips: Enhance imaging and measurement techniques in nanotechnology.
Telecommunications
Gas-Discharge Tubes: Utilized in telecom networks for improved performance.
Flat Panel Displays: Enhance visual quality and energy efficiency.