MWCNTs Isopropanol Dispersion (3wt%, >95%, OD: 20-30 nm, Length 10-30um)
| MWCNTs Isopropanol Dispersion | |
| Product No | NRE-36015 |
| CAS No. | NA |
| Purity | > 95 wt% |
| Average Diameter | 20-30 nm |
| Average Length | 10-30 um (TEM) |
| Special Surface Area(SSA) | > 110 m2/g (BET) |
| Tap Density | 0.28g/cm3 |
| True Density | 2.1 g/cm3 |
| Electric Conductivity | > 100 S/cm |
Multi-Walled Carbon Nanotubes
MWCNTS Isopropanol dispersion are nano structured materials consisting of multiple concentric layers of carbon atoms arranged in a cylindrical form. These structures can vary in the number of walls, typically ranging from two to several dozen layers, which contributes to their unique properties. MWCNTS Isopropanol dispersion exhibit exceptional mechanical strength, thermal conductivity, and electrical conductivity, making them valuable in a wide range of applications.
applications:
Composite Materials: are often incorporated into polymers, metals, and ceramics to enhance mechanical strength, electrical conductivity, and thermal stability. They are used in automotive parts, sports equipment, and construction materials.
Electronics: are employed in the development of advanced electronic devices, including field-effect transistors, conductive inks, and touchscreens. Their high electrical conductivity makes them suitable for flexible electronics.
Energy Storage: In batteries and supercapacitors, MWCNTs improve charge storage capacity and cycling stability. They are used in electrode materials to enhance performance and efficiency.
Sensors: are highly sensitive to changes in their environment, making them ideal for gas sensors, biosensors, and chemical sensors. Their large surface area allows for better interaction with target molecules.
Thermal Management: MWCNTs are used in thermal interface materials to improve heat dissipation in electronic devices. Their excellent thermal conductivity helps manage heat in high-performance applications.
Biomedical Applications: MWCNTs are explored for drug delivery, imaging, and cancer therapy due to their ability to be functionalized and biocompatible. They can target specific cells and improve the efficacy of therapeutic agents.
Water Treatment: MWCNTs are investigated for use in filtration and purification processes, as their large surface area and adsorptive properties can help remove contaminants from water.
Nanotechnology: MWCNTs serve as scaffolds in nanotechnology applications, including nanocomposites and nanostructured materials, enhancing properties at the nanoscale.
Composite Materials: MWCNTs are often incorporated into polymers, metals, and ceramics to enhance mechanical strength, electrical conductivity, and thermal stability. They are used in automotive parts, sports equipment, and construction materials.
Electronics: MWCNTs are employed in the development of advanced electronic devices, including field-effect transistors, conductive inks, and touchscreens. Their high electrical conductivity makes them suitable for flexible electronics.
Energy Storage: In batteries and supercapacitors, MWCNTs improve charge storage capacity and cycling stability. They are used in electrode materials to enhance performance and efficiency.
Sensors: MWCNTs are highly sensitive to changes in their environment, making them ideal for gas sensors, biosensors, and chemical sensors. Their large surface area allows for better interaction with target molecules.
Thermal Management: MWCNTs are used in thermal interface materials to improve heat dissipation in electronic devices. Their excellent thermal conductivity helps manage heat in high-performance applications.
Biomedical Applications: MWCNTs are explored for drug delivery, imaging, and cancer therapy due to their ability to be functionalized and biocompatible. They can target specific cells and improve the efficacy of therapeutic agents.
Water Treatment: MWCNTs are investigated for use in filtration and purification processes, as their large surface area and adsorptive properties can help remove contaminants from water.
Nanotechnology: MWCNTs serve as scaffolds in nanotechnology applications, including nano composites and nanostructured materials, enhancing properties at the nanoscale.
