Empty multilayer CNTs for energy storage using Ga graphene for some applications such as digital switches with high on-off ratio (Nano-Microelectronics PhD)

 Empty multilayer CNTs for energy storage  using Ga graphene for some applications such as digital switches with high on-off ratio (Nano-Microelectronics PhD)

Researcher   and author: Dr.   (  Afshin Rashid)

Note: Graphene has outstanding nanoelectronic properties, very high electron mobility, and unparalleled nanoscale conductivity. It is so conductive that it transmits electrons ten times faster than silicon. And plays an important role in  increasing the electronic conductivity with Ga graphene bonding in Nano carbon Tube multilayer CNTs.

To  increase the electronic conductivity with Ga graphene bonding in Nano carbon Tube, a  lot of hydrogen can be stored in the nanotubes for energy applications and fuel cocoons. Have become superconducting. The radius of these superconducting nanotubes is only 6.4 nanometers. Phase transfer  in one or two dimensional systems  where room temperature superconductivity can be found in carbon nanotubes and graphene particles and is based on room temperature conductivity. Electric voltage is generated by the passage of liquid through coils of single-walled carbon nanotubes. This technique is used to  make liquid flow sensors to detect very small amounts of fluids and to generate voltage in  biomedical applications. Liquids with high ionic strength also produce more voltage  .

Because the multilayer carbon nanotubes of the CNTs are hollow, it is possible to place foreign matter inside them. So by putting Ga graphene in it, you can improve both the electrical properties and the energy storage. It limits the use of Ga graphene for some applications, such as digital switches with high on-off current ratios. Fortunately, quantum excitation stimulation and edge effects in uniform, narrow-width (GNRs) and controllable graphene nano-strips are defective. the  increase in electronic conductivity of graphene Ga link in multi-layer carbon nanotubes CNTs nano carbon Tube  covers. Graphene is a pure carbon-based material. Graphene is a simple, regular, hexagonal carbon structure but very strong. Electrically, graphene is divided into semiconductors such as germanium and silicon.Multi-walled carbon nanotubes consist of nested graphene layers  with a diameter of about 233 nanometers. The length of  this nanotube can vary from a few nanometers to a few micrometers  . Modifiable chemical levels, high surface area, unique physical properties  and rhythmic length have led to  increased electronic conductivity by Ga graphene bonding in multi-layer CNTs   . Usually to improve the electrical properties of some materials such as  (carbon glass electrodes) GCE  , carbon paste  electrode, graphite electrodes or graphene electrodes can be  increased electronic conductivity by Ga graphene bond in Nano carbon Tube multilayer CNTs  can be observed .

Conclusion: 

Graphene has outstanding nanoelectronic properties, very high electron mobility, and unparalleled nanoscale conductivity. It is so conductive that it transmits electrons ten times faster than silicon. And plays an important role in  increasing the electronic conductivity with Ga graphene bonding in Nano carbon Tube multilayer CNTs.

Researcher  and author: Dr.   (   Afshin Rashid)

PhD in Nano-Microelectronics