Simulation Process Section in (Electrical Nanoparticles)Electrostatic Nanoparticles (ESD) in The Nanodevice Simulation Process

Note: Electrostatic ESD semiconductor nanoparticles were fabricated using the electrospray process.  Electrospray deposition (ESD) is a method of preparing particles from a gas spray generation route.  The ESD method, which produces nano-sized droplets, combined with solvent evaporation of the nano-droplets can produce nanoparticles whose size is controlled to the nanoscale and create a quantum confinement effect.

The surface atoms of the nanoparticles are not compensated in terms of energy. In general, the results of the energy growth of  the nanoparticles can be expressed as the total energy of the atoms on the surface of the particle. The freedom of movement of the atoms on the surface of the nanostructures  is limited, and only vibrational movements and electron motion are possible. These two electrokinetic reactions  are interdependent because the displacement of the electron clouds of the atoms necessarily changes the vibrational frequencies of the bonds of the nanoparticles' atoms  . On the other hand, the change in the location of the valence electrons in the bonds  changes the polarity of the bond and the objects called the supermolecule. In this case, the electron transfer to a higher energy level becomes possible.

Metal alloys or bimetallic nanoparticles  have high electrostatic ESD properties that make them suitable for  electromagnetic nanomolecules or electromagnetic nanocarriers  . In addition, the electromagnetic properties  of these nanoparticles allow surface active agents to  be placed  on the surface of their nanoparticles,  which can be used to dissolve the nanoparticles  . Surface coating is  an integral part of electromagnetic nanoparticles to be used. Although nanoparticles do not attract each other due to their  superparamagnetic properties,  electromagnetic nanoparticles tend to aggregate and accumulate due to their high surface energy  . Nanomolecular electrostatic stability  is not suitable for nanoparticles; although the repulsion of charges on  the surface of nanoparticles can prevent their aggregation,  these charges are neutralized in the presence of a catalyst or other electrolytes in the  internal environment of electrostatic ESD nanoparticles.

Electromagnetic (Active) properties in  the coating of nanoparticles, like a barrier  , prevent their aggregation, and chemical functionalization  creates suitable and efficient properties for nanoparticles  .  Molecular weight and geometric orientation on the surface of nanoparticles exist in various forms. Layers that fully activate electromagnetic nanoparticles. Prevent nanoparticles from accumulating on top of each other. In addition to organic coatings, core-shell structures  are also used for optimal application of electromagnetic nanoparticles  .

Conclusion:

Electrostatic ESD semiconductor nanoparticles were fabricated using the electrospray process.  Electrospray deposition (ESD) is a method of preparing particles from a gas spray generation route.  The ESD method, which produces nano-sized droplets, combined with solvent evaporation of the nano-droplets can produce nanoparticles whose size is controlled to the nanoscale and create a quantum confinement effect.