Amplification of a large current from two carbon electrodes in the space containing the plasma material that leads to a spark in the gap between the two electrodes in (nanotubes)

Researcher  and author: Dr.   (   Afshin Rashid)



Note: This method of propagation passes a large current through two carbon electrodes in the space containing the plasma material, which leads to a spark in the gap between the two electrodes. 

In this case, more than 30% of the ash produced is carbon nanotubes. A new method for the chemical modification of carbon nanotubes, which involves the radio frequency activation of plasma luminosity, followed by the characteristic chemical reactions of the functional plasma production groups, is carbon nanotubes. For example, graphene chains on electron-guided carbon nanotubes react with plasma and are immobilized by forming base Schiff bonds, which are stabilized by reduction with carbon nanotube particles. Using the same reaction, we also bond oxidized graphene chains with chemically dispersed pre-labeled bonds on reacted carbon nanotubes with CNT carbon nanotubes. In this method, plasma amplification of metal nanotubes and nanoelectronic conductors  Graphene labeling allows the surface immobilization reaction to be performed simply by measuring light radiation. Conductive single-layer (CNT) carbon nanotubes are bonded.



There are strong bonds between the atoms of the nanotubes that make them highly resistant to the effects of tensile forces  An example of the force required to break a carbon nanotube is many times the  force required to break a piece of steel the thickness of a nanotube. In nanotubes, in addition to creating high strength, interatomic bonds make them easy to form and even twist  While steel is only resistant to tensile forces and does not have the necessary flexibility against   torsion. Due to the good strength and ductility of nanotubes, they are used as composites with metal, polymer and  ceramic substrates.




Conclusion :

CNT carbon nanotubes have a fullerene-like structure  that can have a closed end  The name of these nanostructures is derived from  their physical shape in  which graphene tubular sheets with different tubing angles  lead to tubes with  different symmetries. The angle of tubing and the  radius of the tube determine the occurrence of metal or semiconductor properties  in these nanostructures.

Researcher  and author: Dr.   (   Afshin Rashid)

PhD in Nano-Microelectronics