2020
DOI: 10.1088/1751-8121/ab78d1
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Time-dependent rational extensions of the parametric oscillator: quantum invariants and the factorization method

Abstract: New families of time-dependent potentials related to the parametric oscillator are introduced. This is achieved by introducing some general time-dependent operators that factorize the appropriate constant of motion (quantum invariant) of the parametric oscillator, leading to new families of quantum invariants that are almost-isospectral to the initial one. Then, the respective time-dependent Hamiltonians are constructed, and the solutions of the Schrödinger equation are determined from the intertwining relatio… Show more

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Cited by 13 publications
(26 citation statements)
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“…(5) that is a solution of equation ( 4); with , , are arbitrary real numbers, with the constraint − 2 ∕4 = 1. It is worth to mention that for the singular oscillator with constant frequency, there also exists a generalization of the Ermakov invariant which is also explicitly time dependent [33,34,35].…”
Section: Ermakov-lewis Invariantmentioning
confidence: 99%
“…(5) that is a solution of equation ( 4); with , , are arbitrary real numbers, with the constraint − 2 ∕4 = 1. It is worth to mention that for the singular oscillator with constant frequency, there also exists a generalization of the Ermakov invariant which is also explicitly time dependent [33,34,35].…”
Section: Ermakov-lewis Invariantmentioning
confidence: 99%
“…In turn, the parametric oscillator is found to have a constant of motion that defines the appropriate eigenvalue equation [23]. The latter result motivated the systematic research of quantum invariants [25][26][27][28], with applications in the construction of time-dependent wave-packets [29][30][31][32][33][34][35][36][37], Darboux transformations [38][39][40][41], and two-dimensional photonic systems [42], among other. The Swanson oscillator [43] is a very peculiar system that combines both profiles since it is non-Hermitian and time-dependent.…”
Section: Introductionmentioning
confidence: 99%
“…Lewis and Riesenfeld [52] addressed the problem by noticing the existence of a nonstationary eigenvalue equation associated with the appropriate constant of motion (quantum invariant) of the system in which the time dependence appears in the coefficients of the related ordinary differential equation. The latter eigenvalue equation can indeed be factorized in such a way that the Darboux transformation 1 is applied with ease [56,57], resulting in a new quantum invariant rather than a Hamiltonian. Then, the appropriate ansatz allows to determine the respective Hamiltonian and time-dependent potentials with ease [56].…”
Section: Introductionmentioning
confidence: 99%
“…The latter eigenvalue equation can indeed be factorized in such a way that the Darboux transformation 1 is applied with ease [56,57], resulting in a new quantum invariant rather than a Hamiltonian. Then, the appropriate ansatz allows to determine the respective Hamiltonian and time-dependent potentials with ease [56]. The solutions, and the complex-phases introduced by Lewis-Riesenfeld, are inherited from the former system, ensuring an orthogonal set of solutions for the new system.…”
Section: Introductionmentioning
confidence: 99%
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