Coordinates in  nanoparticles  (PhD in Nano-Microelectronics) 

Researcher  and author: Dr.   (   Afshin Rashid)



Or nanoparticles  Nanoparticle in  clusters of metal and metal oxide nano-composites and metal / carbon-carbon nanostructures reverse share) in addition to the  metallic bonds and covalent (Kyvrdynansy important links) that leads to self-organization of the system. At the same time, these bonds can increase the change in the electronic structure of d metals, thereby increasing the number of single electrons and the number of magnetic moments of the atom .

In the manufacture and propagation of nanomaterials, the  results of nanoparticle energy growth can be expressed as the energy of all atomic surface atoms. Obviously, the freedom of movement of surface atoms is limited and only vibrational movements and the movement of electrons are possible. These two kinetic forms are  interdependent because the displacement of the electron clouds of atoms inevitably changes the vibrational frequencies of the bonds of the atoms. On the other hand, the displacement of the valence electrons in the bonds changes the polarity of the bond and the so-called supermolecule bodies  , in which case electron transfer to a higher energy level becomes possible. In this respect, metal / carbon nanostructures are the most interesting species studied. In these nanostructures , metal clusters  interact with the carbon envelope that protects them from the environment, and for this reason these nanostructures are called  metal / carbon nanocomposites. 

Structure of magnetic nanoelectrons in bonds (coordination _ suspension) and paramagnetic resonance of electrons

The application of metal / carbon nanoparticles in the form of fine suspensions and sols at certain intermediates to modify organic and inorganic polymeric materials depends on the paramagnetic resonance of the electron, it is possible to combine these devices with colors, sizes and properties. The study of the band gap structure of these devices, in addition to introducing a method for the performance of one-dimensional systems, has made it possible to improve the nano-microelectric properties of electronic components.

Organic-based devices can be largely mechanically flexible due to the weak intermolecular bonds in their layers. Unlike these organic materials, minerals such as silicon, germanium, and gallium arsenide can only be used in the structure of electronic devices in crystalline states, in which case covalent bonds make flexibility impossible.

Researcher  and author: Dr.   (   Afshin Rashid)

PhD in Nano-Microelectronics