Symmetry and Mesoscopic Physics
Yukalov, Vyacheslav
Symmetry and Mesoscopic Physics - Basel MDPI - Multidisciplinary Digital Publishing Institute 2022 - 1 electronic resource (244 p.)
Open Access
Symmetry is one of the most important notions in natural science; it lies at the heart of fundamental laws of nature and serves as an important tool for understanding the properties of complex systems, both classical and quantum. Another trend, which has in recent years undergone intensive development, is mesoscopic physics. This branch of physics also combines classical and quantum ideas and methods. Two main directions can be distinguished in mesoscopic physics. One is the study of finite quantum systems of mesoscopic sizes. Such systems, which are between the atomic and macroscopic scales, exhibit a variety of novel phenomena and find numerous applications in creating modern electronic and spintronic devices. At the same time, the behavior of large systems can be influenced by mesoscopic effects, which provides another direction within the framework of mesoscopic physics. The aim of the present book is to emphasize the phenomena that lie at the crossroads between the concept of symmetry and mesoscopic physics.
Creative Commons
English
books978-3-0365-2758-1 9783036527598 9783036527581
10.3390/books978-3-0365-2758-1 doi
Research & information: general
Bose systems asymptotic symmetry breaking Bose-Einstein condensation particle fluctuations stability of Bose systems fractals small-angle scattering form factor structural properties dimension spectra pair distance distribution function stochastic dynamics symmetry breaking field-theoretic renormalization group Bose-Einstein condensates density position variance momentum variance angular-momentum variance harmonic-interaction model MCTDHB particle-hole symmetry metal-insulator transition random gap model Monte Carlo simulations structure factor quantum droplet binary Bose-Einstein condensate modulational instability graphene ripple transport symmetry quantum dot Kramers degeneracy spin-orbit interaction tight-binding approach Bose-Einstein condensates Josephson oscillations spontaneous symmetry breaking Thomas-Fermi approximation dynamical chaos ground states perturbation theory
Symmetry and Mesoscopic Physics - Basel MDPI - Multidisciplinary Digital Publishing Institute 2022 - 1 electronic resource (244 p.)
Open Access
Symmetry is one of the most important notions in natural science; it lies at the heart of fundamental laws of nature and serves as an important tool for understanding the properties of complex systems, both classical and quantum. Another trend, which has in recent years undergone intensive development, is mesoscopic physics. This branch of physics also combines classical and quantum ideas and methods. Two main directions can be distinguished in mesoscopic physics. One is the study of finite quantum systems of mesoscopic sizes. Such systems, which are between the atomic and macroscopic scales, exhibit a variety of novel phenomena and find numerous applications in creating modern electronic and spintronic devices. At the same time, the behavior of large systems can be influenced by mesoscopic effects, which provides another direction within the framework of mesoscopic physics. The aim of the present book is to emphasize the phenomena that lie at the crossroads between the concept of symmetry and mesoscopic physics.
Creative Commons
English
books978-3-0365-2758-1 9783036527598 9783036527581
10.3390/books978-3-0365-2758-1 doi
Research & information: general
Bose systems asymptotic symmetry breaking Bose-Einstein condensation particle fluctuations stability of Bose systems fractals small-angle scattering form factor structural properties dimension spectra pair distance distribution function stochastic dynamics symmetry breaking field-theoretic renormalization group Bose-Einstein condensates density position variance momentum variance angular-momentum variance harmonic-interaction model MCTDHB particle-hole symmetry metal-insulator transition random gap model Monte Carlo simulations structure factor quantum droplet binary Bose-Einstein condensate modulational instability graphene ripple transport symmetry quantum dot Kramers degeneracy spin-orbit interaction tight-binding approach Bose-Einstein condensates Josephson oscillations spontaneous symmetry breaking Thomas-Fermi approximation dynamical chaos ground states perturbation theory