| Autor: |
Beznosyuk, Sergey A., Zhukovsky, Mark S., Maslova, Olga A., Panin, Victor E, Fomin, Vasily M |
| Předmět: |
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| Zdroj: |
AIP Conference Proceedings; 2020, Vol. 2310 Issue 1, p1-4, 4p |
| Abstrakt: |
The physical foundations and mathematical modeling of subatomic technologies for creating quantum material are considered. It is shown that the characteristic properties of quantum materials fundamentally depend on the nature of quantum processes occurring at subatomic and supra-atomic levels of scale. The key role belongs to subatomic quantum phenomena. The special properties of quantum materials are explained by effects of quantum entanglement of compound quasiparticles at subatomic and supra-atomic levels of scale. It is shown that under the influence of attosecond pulses, the temporal evolution of nonequilibrium processes of formation of quantum material begins with the local initiation of subatomic excitation of entangled electron pairs. Non-equivalent transformations of entangled electron pairs create the boundaries of the spatial box that holds a certain part of the electron Fermi gas and a system of nuclei inside the Coulomb blockade. Thus, a nanoelectromechanical system is formed as a quantum compound quasiparticle of the next supraatomic level. A set of quantum nanoelectromechanical systems provide a mesoscale matrix of electromechanical interfaces in the nonequilibrium condensed state of the quantum material. Attophysical quantum nanoelectromechanical processes of bi-electronics and femtochemical quantum nanomolecular processes of traditional electronics are mutually complemented on a supra-atomic scale from tenths of a nanometer (atom size) to several nanometers of quantum material. [ABSTRACT FROM AUTHOR] |
| Databáze: |
Complementary Index |
| Externí odkaz: |
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