Product Properties
Ni coated Multi-walled carbon nanotube (MWCNTs)
Outside diameter: 8-15nm
Ni Content: >60 wt%
Ni Content: >60 wt%
CNTs Content: >38 wt%
Length: ~50 um
SSA: 60 m2/g
CNTs Content: >38 wt%
Length: 10-30 um
SSA: 60 m2/g
SSA: 60 m2/g
CNTs Content: >38 wt%
Length: 10-30 um
SSA: 70 m2/g
SSA: 70 m2/g
Ni coated Multi-walled carbon nanotube (MWCNTs)
Outside diameter: 30-50nm
Ni Content: >60 wt%
Outside diameter: 30-50nm
Ni Content: >60 wt%
CNTs Content: >38 wt%
Length: <10 um
SSA: 50 m2/g
SSA: 50 m2/g
Ni coated Multi-walled carbon nanotube (MWCNTs)
Outside diameter: 30-80nm
Ni Content: >60 wt%
Outside diameter: 30-80nm
Ni Content: >60 wt%
CNTs Content: >38 wt%
Length: <10 um
SSA: 40 m2/g
SSA: 40 m2/g
Nickel-coated multi-walled carbon nanotubes (Ni-MWCNTs) combine the exceptional properties of carbon nanotubes (CNTs) with the magnetic and catalytic characteristics of nickel, leading to materials with enhanced features and functionalities.
- Improved Conductivity: The inherent high electrical conductivity of MWCNTs is further enhanced with nickel coating, facilitating their use in applications requiring efficient current transfer, such as in electrodes for batteries and capacitors, and in conductive composites.
- Reinforcement Material: The combination of nickel and MWCNTs results in a composite material that exhibits superior mechanical strength and toughness. This makes Ni-MWCNTs ideal as a reinforcing agent in polymers, metals, and ceramics to improve their mechanical properties.
- Catalysis: Nickel’s catalytic properties, combined with the high surface area of MWCNTs, make Ni-MWCNTs efficient catalysts for chemical reactions, including hydrogenation processes and as electrodes in electrocatalysis for fuel cells and electrolyzers.
- Heat Dissipation: The thermal conductivity of MWCNTs is further improved with a nickel coating, making Ni-MWCNTs suitable for use in thermal management applications, such as in heat sinks, thermal interface materials, and in cooling systems for electronics.