nanotransistors and nanoelectronic properties are significantly improved, such as: increase in yang coefficient, elastic strength, resistance to deformation due to heat, fire resistance

In the propagation of nanotransistors and nanoelectronic properties are significantly improved, such as: increase in yang coefficient, elastic strength, resistance to deformation due to heat, fire resistance (PhD in nano-microelectronics)

Researcher  and author: Dr.   (   Afshin Rashid)

Note: In the amplification of nano-transistors and nano-chips, the extraordinary nano-electronic properties of each grain are also used effectively, while it also increases dramatically in the amplified components  , because each of its tiny nano-electron components is from hundreds to Thousands of layers are formed. 

In the propagation of nanotransistors and nanochips, the properties of nanoelectronics are significantly improved  , such as: increase in Yang coefficient, elastic strength, resistance to deformation due to heat, fire resistance , resistance barrier (ionic conductivity) Another advantage is that they do not have a significant effect on the optical properties of the  polymer, the optical thickness of a single nano-electron layer is much less than the wavelength of visible light, and they are optically transparent and almost colorless.

In the amplification of nanotransistors and nanopips based on electronic nanotechnology, the change in the distance between the atoms of the particles and the geometry of the particles also affect the electronic properties of the material. In the structure of nanoparticles and  resistance barrier, the  electronic quantity that is more easily available is the ionization potential, and in the ionization potential in the size  of small nanoparticles, the nanostructure (finer particles) is more, ie with increasing particle size, their ionization potential decreases. It is found that increasing the surface-to- volume ratio and  changes in geometry and electronic structure have a strong effect on the chemical interactions of matter, and for example the activity of small particles  changes with the number of atoms (and therefore the particle size).

In the amplification of nanotransistors and nanochips, two methods are considered for manufacturing:  bottom-up manufacturing method and top-down manufacturing method. In the bottom-up construction method, tools and materials are made from the molecular surface based on the principles of molecular chemistry, just like a wall made by stacking  brick by brick. In the top-down manufacturing method, nano-objects are made in larger quantities without atomic control.

Conclusion : 

In the propagation of nano-transistors and nano-chips, the extraordinary nano-electronic properties of each grain are also used effectively, while in the amplified components it also increases  dramatically, because each of its tiny nano-electron components is from hundreds to thousands of layers. Composed. 

Researcher  and author: Dr.   (   Afshin Rashid)

PhD in Nano-Microelectronics