PlanetPhysics/Time Dependent Harmonic Oscillators

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Time-dependent harmonic oscillators[edit | edit source]

Nonlinear equations are of increasing interest in Physics; Riccati equation and Ermakov systems enter the formalism of quantum theory in the study of cases where exact analytic Gaussian wave packet (WP) solutions of the time-dependent Schr\"odinger equation (SE) do exist, and in particular, in the harmonic oscillator (HO) and the free motion cases.

One of the simplest examples of such nonlinear equations is the Milne--Pinney equation: ${\displaystyle d^{2}x/dt^{2}=~-~{\omega }^{2}(t)x+kx^{3},}$ (1) where ${\displaystyle k}$ is a real constant with values depending on the field in which the equation is to be applied.

Ermakov systems[edit | edit source]

This equation was introduced in the nineteenth century by V.P. Ermakov, as a way of looking for a first integral for the time--dependent harmonic oscillator. He employed some of Lie's ideas for dealing with ordinary differential equations with the tools of classical geometry. Lie had previously obtained a characterization of non-autonomous systems of first-order differential equations admitting a superposition rule: ${\displaystyle dx_{i}/dt=Yi(t,x),i=1,...,n,}$ (2).

This approach has been recently reformulated from a geometric perspective in which the role of the superposition function is played by an appropriate algebriac connection. This geometric approach allows one to consider a superposition of solutions of a given system in order to obtain solutions of another system as a kind of mathematical construction that might be generalized even further; such a superposition rule may be understood from a geometric viewpoint in some interesting cases, as in the Milne--Pinney equation (1), or in the Ermakov system and its generalisations. One recalls here that Ermakov systems are defined as systems of second-order differential equations composed by the Milne--Pinney differential equation (1) together with the corresponding time--dependent harmonic oscillator.

Ermakov systems have been also broadly studied in Physics since their introduction in the nineteenth century. They also appear in the study of the Bose--Einstein condensates, cosmological models, and the solution of time--dependent harmonic or anharmonic oscillators. Several recent reports are concerned with the use Hamiltonian or Lagrangian structures in the study of such a system, and many generalisations or new insights from the mathematical point of view have ben thus obtained. Ermakov--Lewis invariants naturally emerge as functions defining the foliation associated to the superposition rule. It has been shown by Ermakov in 1880 that the system of differential equations coupled via the possibly time-dependent frequency ${\displaystyle \omega }$, leads to a dynamical invariant that has been rediscovered by several authors in the 20th century: ${\displaystyle I_{L}=0.5[(d\eta /dt)~\alpha ~-~\eta (d\alpha /dt)]^{2}+(\eta ~\alpha )^{2}=const.22:34,25June2015(UTC)~~(3)}$ (3)

It is straightforward to show that ${\displaystyle d/dt(I_{L})=0.}$ The above Ermakov invariant ${\displaystyle I_{L}}$ depends not only on the classical variables ${\displaystyle \eta (t)}$ and its time derivative, but also on the quantum uncertainty related to ${\displaystyle \alpha (t)}$ and its time derivative. Additional interesting insight into the relation between variables ${\displaystyle \eta }$ and ${\displaystyle \alpha }$ can be obtained by considering also the Riccati equation.

All Sources[edit | edit source]

^{[1] [2] [3] [4] [5] [6] [7] [8] [9] [10] [11] [11] [12] [13] [14] [15] [16]}

References[edit | edit source]

1. ↑ Dieter Schuch. 2008. Riccati and Ermakov Equations in Time--Dependent and Time--Independent Quantum Systems. Symmetry, Integrability and Geometry: Methods and Applications (SIGM) , {\mathbf 4}, 043: 16 pages.
2. ↑ R. Goodall and P. G. L. Leach. Generalised Symmetries and the Ermakov-Lewis Invariant., Journal of Nonlinear Mathematical Physics. Volume {\mathbf 12}, Number 1, (2005), 15--26. (Letter)
3. ↑ Grammaticos B. and Dorizzi B., Two-dimensional time-dependent Hamiltonian systems with an exact invariant. Journal of Mathematical Physics 25 (1984) 2194--2199.
4. ↑ Kaushal R.S., Quantum analogue of Ermakov systems and the phase of the quantum wave function, Intnl. J. Theoret. Phys. , {\mathbf 40}, (2001), 835--847.
5. ↑ Korsch H.J., Laurent H., Milne's differential equation and numerical solutions of the Schr¨odinger equation. I. Bound-state energies for single-- and double-- minimum potentials,J. Phys. B: At. Mol. Phys. {\mathbf 14} (1981), 4213--4230.
6. ↑ Korsch H.J., Laurent H. and Mohlenkamp., Milne's differential equation and numerical solutions of the Schr\"odinger equation. II. Complex energy resonance states, J. Phys. B: At. Mol. Phys. , {\mathbf 15}, (1982), 1--15.
7. ↑ Schuch D., Relations between wave and particle aspects for motion in a magnetic field, in New Challenges in Computational Quantum Chemistry. , Editors R. Broer, P.J.C. Aerts and P.S. Bagus, University of Groningen,(1994), 255--269.
8. ↑ Maamache M. Bounames A., Ferkous N., Comment on "Wave function of a time-dependent harmonic oscillator in a static magnetic field.", Phys. Rev. A {\mathbf 73}, (2006), 016101, 3 pages.
9. ↑ Ray J.R., Time-dependent invariants with applications in physics, Lett. Nuovo Cim. , {\mathbf 27}, (1980), 424--428.
10. ↑ Sarlet W., Class of Hamiltonians with one degree-of-freedom allowing applications of Kruskal's asymptotic theory in closed form. II, Ann. Phys. (N.Y.) 92 (1975), 248--261.
11. ↑ ^{11.0 11.1} Lewis H.R., Leach P.G.L., Exact invariants for a class of time-dependent nonlinear Hamiltonian systems, J. Math. Phys. 23 (1982), 165--175. Cite error: Invalid <ref> tag; name "LHR-LP82" defined multiple times with different content
12. ↑ "Ermakov's Superintegrable Toy and Non-Local Symmetries." P. G. L. Leach, A. Karasu, M. C. Nucci, and A. Andriopoulos, SIGMA, 1 (2005) 018 /www.emis.de/journals/SIGMA/2005/Paper018/
13. ↑ Sebawa Abdalla M., Leach P.G.L., Linear and quadratic invariants for the transformed Tavis--Cummings model, J. Phys. A: Math. Gen. , {\mathbf 36} (2003), 12205--12221.
14. ↑ Sebawa Abdalla M., Leach P.G.L., Wigner functions for time--dependent coupled linear oscillators via linear and quadratic invariant processes, J. Phys. A: Math. Gen. , {\mathbf 38}, (2005), 881--893.
15. ↑ Kaushal R.S., Classical and quantum mechanics of noncentral potentials. A survey of 2D systems, Springer, Heidelberg, (1998).
16. ↑ Ermakov V., Second-order differential equations. Conditions of complete integrability. Universita Izvestia Kiev Ser III 9 (1880) 1--25, trans Harin AO.