Nickel Carbon Nanotubes
Nickel Carbon Nanotubes are generally immediately available in most volumes. Additional technical, research and safety (MSDS) information is available. Carbon Nanotubes are Single-Walled, Double Walled and Multi-Walled black nano scale cylindrical tubes of graphitic carbon with numerous applications. Carbon Nanotubes are the stiffest and strongest known fibers and have unique electrical properties.
|Nickel Carbon Nanotubes|
|CAS No.||7440-02-0 / 7440-44-0|
|Average Length||up to 200µm|
|Molecular Weight||70.7041 g/mol|
Nickel Carbon Nanotubes are generally immediately available in most volumes. Additional technical, research, and safety (MSDS) information are available. Carbon Nanotubes are Single-Walled, Double Walled and Multi-Walled black nanoscale cylindrical tubes of graphitic carbon with numerous applications. Carbon Nanotubes are the stiffest and strongest known fibers and have unique electrical properties. When used as reinforcement fibers, carbon nanotubes can improve the quality and properties of metal, polymer, and ceramics. Applications for AE Carbon Nanotubes™ include flat-screen displays, scanning probe microscopes in brushes for commercial electric motors, and in sensing devices and because of their strength in numerous aerospace and automotive uses, in body armor and tear-resistant cloth fibers and textiles, and stronger and lighter sports equipment.
Carbon nanotubes can behave like a conductive metallic or semiconductor depending on their structure, which is useful for nanoscale electronic devices and in electrically conductive films in coatings, plastics, nanowire, nanofiber, and in certain bioscience applications. Recently, carbon nanotubes have been demonstrated to create the “darkest” known material absorbing all wavelengths or “colors” of light which will prove useful in solar and electronic applications. When combined with Aluminum, Copper, Magnesium, Nickel, Titanium, and Tin, Single-Walled Carbon Nanotube materials reveal enhanced tensile strength, hardness, and elastic modulus characteristics. Titanium/Carbon Nanotube composites, research shows demonstrate a considerable increase in tensile stress, hardness, and yield stress. In an additional study, when compared to pure Titanium, Titanium/Carbon Nanotube composites displayed increased property hardness of the metal as well as improved elastic modulus.