Nano-electromagnetic interactions based on the energy characteristic of nano-electrons (nano-structures) based on nano-microelectronics (PhD)
Researcher and author: PhD student Afshin Rashid
Note: The important characteristic of all nanostructures is that the number of atoms (surface) is greater than the number of atoms (volume). This ratio increases with decreasing size (nanoparticles). Therefore, the size of nanoparticles is an important feature.
The shapes and sizes of nanostructures are naturally determined by their composition and conditions. The properties of the nanostructures, in turn, determine the authenticity of the nanostructures' features and their potential applications. Introduced in the range of 1 to 1000 nm as nanostructures, an important feature of nanostructures is the control of the processes of the organization itself. The extent of the change in the activity of the nanostructure depends on the nature and shape of the nanostructure. With However, if the energy field of nano-particles with energy exposure to electro-magnetic analogy, and if within a certain wavelength, the occurrence of chemical reactions in materials under irradiation dramatic changes the activity of nanoparticles to the size of 100nm will be dramatic.
The surface atoms of the nanostructures are not energetically compensated. In general, the growth of nanoparticle energy can be expressed as the total energy of atoms on the surface of the particle. At the particle surface of nanostructures the freedom of movement of the surface atoms is limited and only vibrational movements and movement of electrons are possible. The two kinetic types are interdependent because the displacement of the electron clouds of atoms will inevitably alter 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 so-called super-molecule objects, thus allowing the electron to move to a higher energy level.
Conclusion
Nanoparticle bonds on the surface of nanostructures can enhance electron deformation and thus increase the number of individual electrons and the number of nano-electromagnetic atoms in nano-electromagnetic interactions.
Author: Engineer Afshin Rashid