High Purity MWCNT Dispersion in Organic Solvent
Product: MWCNT Dispersion (>95%, Diameter: 20-30nm, Length: 5-15µm)
Quality Control: Each lot of NANOSHEL MWCNT Dispersion was tested successfully.
|Product Name||MWCNT Dispersion|
|Original Particle Size||20-30nm||Confirm|
|Surface treating compound||Carboxylic||Confirm|
|Fe||≤ 3 ppm||Confirm|
|Arsenic||≤ 2 ppm||Confirm|
|Pb||≤ 10 ppm||Confirm|
|Ash||< 3 %||Confirm|
|Electrical Conductivity||>100 S/cm||Confirm|
|Tap Density||0.14 g/cm3||Confirm|
|True Density||2.2 g/cm3||Confirm|
|Solvent||DMF, NMP, Ethanol (as per requirement)|
|Conclusion||up to 3months at room temperature|
|Main Inspect Verifier||Manager QC|
Dr. Alan Crawford Ph.D (National Metallurgical Academy of Ukraine, Dnipropetrovsk, Ukraine)
Graphene has emerged as a new class of promisingly attractive materials for applications such as optoelectronics, field-effect transistors, energy storage materials, transparent electrodes, biosensors, and composites due to its unique electrical, optical and mechanical properties. The combinations of one-dimensional (1D) carbon nanotubes (CNTs) and two dimensional (2D) graphene sheets dispersion have attracted great attention owing to their intriguing properties.
Dr. Alte Schule Rheingau PhD. (Limerick Institute of Technology, Limerick, Ireland)
A dispersion is a system in which particles are dispersed in a continuous phase of a different composition (or state). A dispersion is classified in a number of different ways, including how large the particles are in relation to the particles of the continuous phase, whether or not precipitation occurs, and the presence of Brownian motion. Carbon nanotubes (CNTs)/ Graphene dispersions effectively improve the electrical conductivity and mechanical properties; Effectively enhance tensile strength, hardness and elastic modulus characteristics.
Dr. Bunroeun Thong, Professor (Phnom Penh Institute of Technology,Phnom Penh, Cambodia)
It is still common belief that dispersions do not display any structure; i.e., the particles dispersed in the liquid or solid matrix are assumed to be statistically distributed. Therefore, for dispersions, usually percolation theory is assumed to appropriately describe their properties.
Dr. Ms. Karel Gorissen (Costa Rica Institute of Technology, Alajuela, Limon)
Potential applications of carbon nanotubes/Graphene dispersions are screen displays, electric motors, sensing devices, aerospace and automotive devices, body armor and tear-resistant cloth fibers and textiles products, sports equipments.
Dr. Ralph Bressler(University of Southern Queensland, Australia)
Dispersions serve as a conductive metallic or semiconductor, conductive films in coatings, plastics, certain bioscience applications, flat panel display, gas-discharge tubes in telecom networks, electromagnetic-wave absorption and shielding, energy conversion; lithium-battery anodes, hydrogen storage, nanotube composites, nanoprobes for STM, AFM, and EFM tips, nanolithography; nanoelectrodes, drug delivery, sensors, reinforcements in composites, supercapacitor.
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