Your search keyword '"hidden symmetry"' showing total 5 results

1. Hidden symmetry and excitonic transitions in the quantum well

Author

Kazaryan, E.M., Petrosyan, L.S., and Sarkisyan, H.A.

Subjects

*QUANTUM wells, *COULOMB potential, *ELECTRIC fields, *EXCITON theory

Abstract

Abstract: In this article it is shown that, Sommerfeld''s coefficients for excitonic transitions in quantum wells are determined only with the principle quantum number within the framework of two-dimensional Coulomb potential. This is a consequence of hidden symmetry of two-dimensional Coulomb problem, conditioned by the existence of two-dimensional analog of the Runge–Lentz vector. For the narrow gap semiconductor quantum well with the non-parabolic dispersion law of electron and hole in the two-band Kane model it is shown that two-dimensional excitonic states are described in the frames of an analog of Klein–Gordon equation with the two-dimensional Coulomb potential. The non-stability of the ground state of the two-dimensional Kane''s exciton is shown. [Copyright &y& Elsevier]

Published

2008

2. Twist buckling and the foldable cylinder: an exercise in origami

Author

Hunt, Giles W. and Ario, Ichiro

Subjects

*MECHANICAL buckling, *STRAINS & stresses (Mechanics), *DEFORMATIONS (Mechanics), *MATERIAL plasticity

Abstract

Abstract: Basic mechanisms for the buckling of a thin cylindrical shell under torsional loading are reviewed from a post-buckling perspective. Deflections are considered so far into the large-deflection range that the shell is allowed to fold to a flat two-dimensional form, in a mechanism reminiscent of a deployable structure. Critical and initial post-buckling effects are explored through concepts of energy minimization and hidden symmetries. For comparisons with the final large-deflection folded shape, a truss element program is employed. It is shown that, as buckling develops, the mode shape must change to accommodate both the symmetry-breaking aspects of the predominately inwards deflection, and the rotation of peak and valley lines of the buckle pattern necessary to accommodate the geometry of the final folded shape. [Copyright &y& Elsevier]

Published

2005

3. Nonlinear supersymmetry in quantum mechanics: algebraic properties and differential representation

Author

Andrianov, A.A. and Sokolov, A.V.

Subjects

*QUANTUM theory, *HERMITIAN forms

Abstract

We study the nonlinear (polynomial, N-fold,…) supersymmetry algebra in one-dimensional QM. Its structure is determined by the type of conjugation operation (Hermitian conjugation or transposition) and described with the help of the Hamiltonian projection on the zero-mode subspace of supercharges. We show that the SUSY algebra with transposition symmetry is always polynomial in the Hamiltonian if supercharges represent differential operators of finite order. The appearance of the extended SUSY with several (complex or real) supercharges is analyzed in details and it is established that no more than two independent supercharges may generate a nonlinear superalgebra which can be appropriately specified as N=2 SUSY. In this case we find a nontrivial hidden symmetry operator and rephrase it as a nonlinear function of the Hamiltonian on the physical state space. The full N=2 nonlinear SUSY algebra includes “central charges” both polynomial and nonpolynomial (due to a symmetry operator) in the Hamiltonian. [Copyright &y& Elsevier]

Published

2003

4. Circular binary star and an interstellar interloper: The analytical solution.

Author

Oks, E.

Subjects

*BINARY stars, *TWO-body problem (Physics), *ANALYTICAL solutions, *ANGULAR momentum (Mechanics), *THREE-body problem, *BINARY number system

Abstract

• An analytical solution for the motion of an interstellar interloper around a circular binary • This physical systems has a higher than geometrical symmetry • In the general case, the angular momentum of the interloper rotates around the binary's axis • Explicit equation of the motion for an interloper coplanar with the binary • Correction of the angle of deflection of the interloper due to the 3-body nature of the system We consider an interstellar interloper moving at a relatively large distance from a circular binary star. We use the analytical method of separating rapid and slow subsystems, the rapid subsystem being the binary and the slow subsystem being the interstellar interloper. We show that due to the higher than geometrical symmetry of the problem, in addition to the conservation of the energy and the projection of the angular momentum on the axis of the rotation of the binary, the square of the angular momentum is also conserved. In the course of the time evolution, the vector of the angular momentum rotates about that axis at the constant angle to the axis. After obtaining this general counterintuitive result, we focus at the case where the interstellar interloper is coplanar with the binary. We provide an explicit equation of the motion of the interloper. Then we calculate analytically the angle of deflection of the interloper from the straight line. We analyze the difference in the angle of deflection between this three-body problem and the corresponding two-body problem: we show that this difference remains almost constant (a negative constant) at the range of the eccentricities of the interloper trajectory relatively close to unity and linearly increases (by the absolute value, remaining negative) with the eccentricity as the latter becomes much greater than unity. [ABSTRACT FROM AUTHOR]

Published

2021

5. Analytical solution for the three-dimensional motion of a circumbinary planet around a binary star.

Author

Oks, E.

Subjects

*BINARY stars, *ANALYTICAL solutions, *ATOMIC physics, *RYDBERG states, *PLANETS, *ELLIPTICAL orbits, *STELLAR orbits

Abstract

• An analytical solution for a stable three-dimensional motion of a circumbinary planet. • The orbital plane of the planet undergoes simultaneously two different precessions. • It is mathematically equivalent the motion of a satellite around an oblate planet. • It is mathematically equivalent to a Rydberg atom a high-frequency field. • All of the above physical systems have a higher than geometrical symmetry. By using the method of separating rapid and slow subsystem, we obtain an analytical solution for a stable three-dimensional motion of a circumbinary planet around a binary star. We show that the motion of the planet is more complicated than it was obtained for this situation analytically by Farago and Laskar (2010). Namely, in addition to the precession of the orbital plane of the planet around the angular momentum of the binary (found by Farago and Laskar (2010)), there is simultaneously the precession of the orbital plane of the planet within the orbital plane. We show that the frequency of this additional precession is different from the frequency of the precession of the orbital plane around the angular momentum of the binary. We demonstrate that this problem is mathematically equivalent both to the problem of the motion of a satellite around an oblate planet and to the problem of a hydrogen Rydberg atom in the field of a high-frequency linearly-polarized laser radiation, thus discovering yet another connection between astrophysics and atomic physics. We point out that all of the above physical systems have a higher than geometrical symmetry , which is a counterintuitive result. In particular, it is manifested by the fact that, while the elliptical orbit of the circumbinary planet (around a binary star) or of the satellite (around an oblate planet) or of the Rydberg electron (in the laser field) undergoes simultaneously two types of the precession, the shape of the orbit does not change. The fact that a system, consisting of a circumbinary planet around a binary star, possesses the hidden symmetry should be of a general physical interest. Our analytical results could be used for benchmarking future simulations. [ABSTRACT FROM AUTHOR]

Published

2020