Nano-quantum bonding and nano-electronic memory (PhD in nano-microelectronics) 

Researcher  and author: Dr.   (   Afshin Rashid)



Note: The attractiveness of nanotechnology stems from the unique quantum and surface phenomena that matter at the nanoscale, enabling new applications and interesting materials. The goal of evolutionary nanotechnology is to improve existing processes, materials, and applications by shrinking the nanosphere and ultimately taking full advantage of the unique quantum and surface phenomena that matter represents at the nanoscale.  

Quantum nanostructures  operate on a very small scale through the use of matter, depending on and based on advances in nanotechnology. Using nanotechnology in quantum computing and other similar electronic technologies, there are  two basic principles at the core of nanotechnology: First, the smaller the material, the higher the relative surface area of ​​the material. And the second is the loss of bulky properties instead of quantum phenomena when it reaches such a small scale. Quantum nanotechnology is based on the principle of electronic tunneling. The basic theory is that a particle enclosed in a one-dimensional nano-memory cannot escape unless the electron makes its way out of the enclosure. This is a phenomenon that is exhibited only by quantum matter and is not seen by any bulky substance. This principle can be extended to include all 3D - the so-called particle in a 3D nano-memory. The amount of electron confinement that enters a substance determines its dimension - because quantum dimensions are relative to the confinement of electrons (and in which dimensions electrons operate) more than the atomic spatial arrangement. Quantum dots are probably the most well-known quantum structure in nanoparticles. The interesting thing about quantum dots is that they are electronically constrained in all three dimensions, so they are classified as zero-dimensional materials.



Quantum dots are an interesting class of materials, and many of them are functional (usually customizable). They are semiconductor in nature and are often referred to as artificial atoms because they have discrete electronic states - that is, states can only receive certain amounts of energy (unlike bulky materials). Quantum dots are now considered in many applications, such as electronic nano-memory.  Quantum nanowires, otherwise known as nanowires, are a one-dimensional electrically conductive structure with electrons enclosed in two dimensions. They are known as "wires" because the movements of the electrons are limited in a transverse direction, that is, along the wire, making them work like ordinary wires. They are used to transmit electrons in electronic nano-memories, but only certain energy levels can be used because their bands are also discrete. One of the main advantages of quantum wires is their high image ratio, in which the length of the wire can be up to 1000 times its width. In the internal structure of nano-quantum electronic memories, electrons can tunnel and connect nanopotential cavities to form a lattice supercharger. These supergrids contain nanobonds that travel the length of the connected potential hole, meaning that electrons can move easily between the holes, enabling the super lattice to provide excellent charge-carrying and in some cases superconducting properties. To show himself. This produces quantum nano-memory.



Conclusion:

The appeal of nanotechnology stems from the unique quantum and surface phenomena that matter at the nanoscale, enabling new applications and exciting materials. The goal of evolutionary nanotechnology is to improve existing processes, materials, and applications by shrinking the nanosphere and ultimately taking full advantage of the unique quantum and surface phenomena that matter represents at the nanoscale.  

Researcher  and author: Dr.   (   Afshin Rashid)

PhD in Nano-Microelectronics