Home » Graphene Nanoplatelets (C, Purity: 99.5%,Thickness: 2-4nm)

GRAPHENE NANOPOWDER

Stock No. CAS MSDS Specification COA
NS6130-12-000298 7782-42-5 MSDS pdf Specification pdf COA pdf

Graphene Nanoplatelets (C, Purity: 99.5%,Thickness: 2-4nm)

Graphene Nanoplatelets

Graphene Nanoplatelets (C, Purity: 99.5%,Thickness: 2-4nm)

Quality Control: Each lot of Graphene Nanoplatelets was tested successfully.

SEM-Graphene Nanoplatelets

SEM-Graphene Nanoplatelets

 
Product Graphene Nanoplatelets
Stock No NS6130-12-000298
CAS 7782-42-5 Confirm
HS Code 38019000 Confirm
Purity 99.5% (Metal base) Confirm
Lateral size ~5µm (± 3%) Confirm
Thickness 2-4nm Confirm
Color Black Confirm
Density ~ 2.3 g/cm3 Confirm
Bulk Density ~ 0.10 g/ml Confirm
Morphology Flaky Confirm
SSA 20-40 m2/g Confirm
pH 6-7 Confirm
Ash <0.5% Confirm
Layer 4-6layers (50-80%) Confirm
Lattice Defects Low to medium concentration Confirm
Impurities < 0.1%, H2O~0.02% (quartz + mica) Confirm
Electrical Conductivity 80000 S/m Confirm
Main Inspect Verifier Manager QC

Typical Chemical Analysis

Assay 99.5%

Expert Reviews

Dr. Baron Augustin, Ph.D (TUM), (Technical University of Munich, Germany)

Graphene Nanoplatelets: Graphene is an atomic-Scale honeycomb Lattice made of Carbon atoms. Graphene is undoubtedly emerging as one of the most promising nanomaterials because of its unique combination of novel electronic, optical and mechanical  properties which opens a way for its exploitation in a wide spectrum of applications ranging from electronics to optics,  photonics, composite materials, energy generation, sensors, and biodevices.


Dr. Darren Chandler, Ph.D, (Manchester Metropolitan University, U.K)

Graphene Nanoplatelets: Graphene remains capable of conducting electricity even at the limit of nominally zero carrier concentration because the electrons don’t seem to slow down or localize. The electrons moving around carbon atoms interact with the periodic potential of graphene’s honeycomb lattice, which gives rise to new quasi particles that have lost their mass, or rest mass. Graphene never stops conducting and they travel far faster than electrons in other semiconductors.


Dr. Ms. Cristiana Barzetti, (University of Cagliari-Department of Chemical Engineering and Material Science, Italy)

Graphene Nanoplatelets: The most common techniques available for the production of graphene includes: Chemical Vapour Deposition, Micromechanical Cleavage, Epitaxial Growth on SiC Substrates, Chemical Reduction of Exfoliated Graphene Oxide, Liquid Phase Exfoliation of graphite and unzipping of Carbon Nanotubes.


Dr. Jang Huang, Ph.D, (Shandong Science and Technology University, China)

Graphene Nanoplatelets: Graphene based nanomaterials have many promising applications in numerous areas: Graphene for energy applications: improves both energy capacity and charge rate in rechargeable batteries, promising approach for making solar cells, promising substrates for catalytic systems, Sensor applicationsIn flexible, stretchable and foldable electronics,  nanoelectronic applicantsphotodetectorsCoatings, drug deliverybio-imaging, Tissue engineering etc.


Dr. Mark Brown, (Georgia Institute of Technology in Atlanta,USA)

Graphene Nanoplatelets: Graphene appears to be most effective material for electromagnetic interference (EMI) shielding. Graphene conducts heat better than any other known material. Graphene is a disruptive technology, one that could open up new markets and even replace excisting technologies or materials.


Graphene Nanoplatelets

Graphene Nanoplatelets


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