Home » Graphite Nanoparticles (C, Purity: 99.5%, APS: <100nm, , Natural Graphite)
Helia-22®
Product | Graphite Nanopowder | |
Stock No | NS6130-01-113 | |
CAS | 7782-42-5 | Confirm |
Purity | 99.5 % | Confirm |
APS | <100nm | Confirm |
Molecular Formula | C | Confirm |
Molecular Weight | 12.01 g/mol | Confirm |
Form | Powder | Confirm |
Color | Black | Confirm |
Density | 1.8 g/cm³ | Confirm |
Melting Point | 3550 °C | Confirm |
Boiling Point | 4027 °C | Confirm |
Quality Control | Each lot of Graphite Nanopowder was tested successfully. | |
Main Inspect Verifier | Manager QC |
Assay | 99.5% |
Ash | <0.5% |
H2O | ~0.2% |
Other Metal | < 0.5 % |
Graphite Nanoparticles applications of graphite in nuclear industry includes fabrication and lining of nuclear plant, heat moderator and reflectors thermal column and as secondary shutdown materials. Graphite used in many area of nuclear technology based on its excellent moderator and reflector qualities which are combi almost uniquely with strength and high temperature stability. The function of a moderator is to slow fast neutrons to thermal velocities at which fission in Uranium-235 and Uranium-233 are most efficient nucler graphite was developed for fission reactors.
Graphite Nanoparticles Natural graphite is mostly consumed for refractories, steelmaking, expanded graphite, brake linings, foundry facings and lubricants; Natural graphite has found uses as the marking material (“lead”) in common pencils, in zinc-carbon batteries, in electric motor brushes, and various specialized applications. Aluminum/graphite composites for bearings, pistons, and liners in engines. Carbon adsorbents for gas chromatography Cupper/graphite and silver/graphite nanocomposites for electrical brushes and contact strips; Inorganic filler (graphite/polymer nanocomposites); Support materials for precision metal powder catalysts Graphite/polymer nanocomposites for enhanced electrical conductivity; Metal matrix composites for reduced friction and wear.
Graphite Nanoparticles Gene therapy is a novel and promising approach to treat various diseases caused by genetic disorders, and cancer. Successful gene therapy requires a gene vector that protects DNA from nuclease degradation and facilitates cellular uptake of DNA with high transfection efficiency. The major challenge facing the development of gene therapy is lack of efficient and safe gene vectors. That GO-CS sheets have a high drug payload, and the CPT-loaded GO-CS exhibits better cancer cell killing ability than the pure CPT. Further work on simultaneous loading and delivery of chemical drug and gene by the GO-CS nanocarrier for combined chemo- and gene- therapy is highly desired, to gain an enhanced therapeutic efficacy.
Graphite Nanoparticles is now expanding its territory beyond electronic and chemical applications toward biomedical areas such as precise biosensing through graphene- quenched fluorescence, graphene-enhanced cell differentiation and growth, and graphene-assisted laser desorption/ionization for mass spectrometry. Graphene derivatives based on chemical and physical properties has hindered the biological application of graphene derivatives. The development of an efficient graphene-based biosensor requires stable biofunctionalization of graphene derivatives under physiological conditions with minimal loss of their unique properties.
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Jules L. Routbort, (Argonne National Laboratory, Argonne, USA)
Graphite Nanoparticles can play multi-faceted roles towards enhancing the mechanical, physical and functional attributes of cementitious materials. Graphite nanoplatelets and carbon nanofibers, when compared with carbon nanotubes, offer desired mechanical and physical reduced cost. Dispersion of nanomaterials in the cementitious matrix is critical for effective use of their distinct geometric and engineering properties towards development of higher-performance cementitious nanocomposites. The dispersion and interfacial interaction of nanomaterials in the aqueous medium of cementitious matrix can benefit from proper surface treatment of nanomaterials. The surface modification techniques employed in this study emphasize introduction of hydrophilic groups on graphite nanomaterials to facilitate their dispersion in aqueous media. These include: (i) polymer wrapping of ox