Electrical properties in electronic-plasmonic nanostructures (Electric as properties)

Note:  Nanostructures   can be defined as materials that have at least one external dimension with a size of 1 to 100 nm. And  the particle size of at least half of the particles in the number size distribution must be 100 nm or less. Nanostructures   can occur naturally, be created as byproducts of combustion reactions, or be purposefully produced through engineering to perform a specific function.  These materials can have different physical and chemical properties from their original bulk samples.

Nanostructures   are used to bend in a composite manner in response to the application of electric voltage .  The use of  nanostructures   is widespread in a wide range of industries and consumer products. In nanoscience, the structure of materials determines the relationship between atoms, ions and molecules that make up those materials. To understand the structure of materials, one must first understand the type of connections between atoms and ions .  Chemical bonds determine how atoms and ions are connected. Therefore, the difference between different types of connections can be seen in the characteristics of these links.

Nanostructures Nanostructure  The electronic properties of the two regions are "protected" by a special, so-called topological, different method. And therefore, a new very strong quantum state is created in the transition region. This localized electronic quantum state can now be used as a key feature to produce certain semiconductors, metals or insulators – and possibly even as a feature in nanoelectronics. The shapes and sizes of nanostructures are naturally determined based on their composition and formation conditions. The characteristics  of nanostructures, in turn,  determine the originality of the characteristics of nanostructures and their possible fields of operation. The range of 1 to 1000nm is introduced as the range of nanostructures, the  important feature of nanostructures is to control the processes of the organization itself. The range of nanostructure activity change depends on the nature and shape of the nanostructure. However  , if the energy of the nanoparticle field is comparable to the energy of electromagnetic radiation and if  significant changes are made in a certain range of wavelength with the occurrence of chemical reactions in the irradiated materials, the activity of nanoparticles  up to 100nm will be significant.

Conclusion :

Nanostructures   can be defined as materials that have at least one external dimension with a size of 1 to 100 nm. And  the particle size of at least half of the particles in the number size distribution must be 100 nm or less. Nanostructures   can occur naturally, be created as byproducts of combustion reactions, or be purposefully produced through engineering to perform a specific function.  These materials can have different physical and chemical properties from their original bulk samples.