A Mass-in-Mass Chain and the Generalization of the Dirac Equation with an Eight-Component Wave Function and with Optical and Acoustic Branches of the Dispersion Relation

The paper considers a slightly modified one-dimensional infinite mass-in-mass chain. In the case of the long-wave approximation, which corresponds to the transition to a continuous medium, we obtained a system of two equations, which is a generalization of the classical mechanics Klein–Gordon–Fock e...

Full description

Saved in:
Bibliographic Details
Published in:Russian microelectronics 2023-12, Vol.52 (Suppl 1), p.S299-S305
Main Authors: Turin, V. O., Ilyushina, Y. V., Andreev, P. A., Cherepkova, A. Yu, Kireev, D. D., Nazritsky, I. V.
Format: Article
Language:English
Subjects:
Acoustics
Classical mechanics
Dirac equation
Electrical Engineering
Electrons
Engineering
Free electrons
Mathematical analysis
Partial differential equations
Plane waves
Quantum Informatics: Physics
Quantum mechanics
Quantum physics
Relativistic effects
Wave functions
Citations: Items that this one cites
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:The paper considers a slightly modified one-dimensional infinite mass-in-mass chain. In the case of the long-wave approximation, which corresponds to the transition to a continuous medium, we obtained a system of two equations, which is a generalization of the classical mechanics Klein–Gordon–Fock equation and has both optical and acoustic branches of the dispersion relation. Based on this classical mechanics system of equations, we have proposed a system of two relativistic quantum mechanics equations, which is a generalization of the relativistic quantum mechanics Klein–Gordon–Fock equation. Next, based on this system and following the Dirac approach, we have proposed the generalization of the Dirac equation for a free electron with an eight-component wave function in the form of a system of eight linear partial differential equations of the first order. Unlike the Dirac equation with a four-component wave function, which has only an optical branch of the dispersion relation, the generalized Dirac equation has both optical and acoustic branches of the dispersion relation, each of which has two branches with positive and negative energies, respectively. We have calculated phase and group velocities for all cases. For the positive and negative acoustic branches, the phase and group velocities are equal in modulus to the speed of light. For the positive and negative optical branches, the phase and group velocities have a structure like that of de Broglie waves. In the one-dimensional case, eight linearly independent solutions corresponding to eight combinations of two branches of dispersion, two signs of total energy, and two possible directions of spin orientation, each in the form of four plane waves, are obtained.
ISSN:1063-7397
1608-3415
DOI:10.1134/S1063739723600693