(molecular nanoelectronics)
A short description of the link between molecular and quantum nanoelectronics
Researcher and author: Dr. ( Afshin Rashid)
Note: Quantum nano effects are important in most materials and create different properties than what we are familiar with on a macroscopic scale. Nanophysics forms the basis of many phenomena of medicine, biological sciences and chemistry and is an important interface with these sciences.
Electronic and optical properties and surfaces of various materials are interesting and new. Nano-Quantum is based on the continuous development and refinement of nano-scale imaging techniques whose resolution reaches the atomic scale. Nanoelectronics enters new materials and different fields of nutrition technology, (nano-scale measuring devices, tools for medical diagnosis, energy efficiency and storage, and solar technology) . Quantum physics phenomena can be done with electrons, atoms or Photons and observed in dense matter systems such as metals or semiconductors that play an important role in our daily life. In the nano-quantum world, we observe many surprising and at first glance unusual phenomena - such as quantum particles that can collide in different places at the same time, or quantum jumps whose exact point in time is essentially random. As confusing as these phenomena may seem, we are already seeing signs that will form the basis of the modern technological revolution. There is almost no other field of science that combines basic research and pure technological applications and revolutionary impact as seamlessly as nanoelectronics.
Nano quantum is a hot topic, a rapidly growing field of quantum computing and quantum technology. This function unites quantum nanophysics with nanotechnology to develop, among other things, ultrafast supercomputers and new measurement tools that will revolutionize many areas of science, communications and the Internet. Nanoelectronics brings together many important fields of quantum physics, such as solid state physics of metals, superconductors, semiconductors, high-value magnets, graphene, quantum Hall and topological systems, low temperature physics, scanning probe physics, nano and quantum optics. It exists. Current nanoelectronics technologies in nanomemories hardly meet the demands, but nanotechnology offers better solutions.One of the new information storage tools is the use of nickel quantum dots in nanometer sizes, which are expected to be used to store terabytes of data, even in homes and in personal use.
Conclusion:
Quantum nanoscale effects are important in most materials and create different properties than what we are familiar with at the macroscopic scale. Nanophysics forms the basis of many phenomena of medicine, biological sciences and chemistry and is an important interface with these sciences.
Researcher and author: Dr. ( Afshin Rashid)
Specialized doctorate in nano-microelectronics