Generalized Lennard-Jones Potentials, SUSYQM and Differential Galois Theory

Acosta-Humánez, Manuel F.; Acosta-Humánez, Primitivo B.; Tuiran, E.

doi:10.3842/sigma.2018.099

Cited by 4 publications

(4 citation statements)

References 46 publications

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“…Dynamical systems are very important in the development of different areas, see for example [1] for applications in Quantum Mechanics and see also [5,6,7,8] for applications in Classical Mechanics. In particular, discrete dynamical systems play an important role due to they are an useful tool to understand continuous systems by decreasing its complexity, either by diminish dimensions or passing from continuous to discrete time.…”

Section: Final Remarksmentioning

confidence: 99%

From Poincaré to May: The Genesis of Discrete Dynamics

Martínez-Castiblanco,

Acosta-Humánez

2021

Preprint

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In this paper, the origin of discrete dynamics is stated from a historical point of view, as well as its main ideas: fixed and periodic points, chaotic behaviour, bifurcations. This travel will begin with Poincaré's work and will finish with May's work, one of the most important scientific papers of 20th century.This paper is based on the M.Sc. thesis "Simple Permutations, Pasting and Reversing" ([22]), written by the first author under the guidance of the second author.

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Section: Final Remarksmentioning

confidence: 99%

From Poincaré to May: The Genesis of Discrete Dynamics

Martínez-Castiblanco,

Acosta-Humánez

2021

Preprint

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“…In the first case if m is even then (r, m) ∈ C 2 ∪ C 3 , otherwise due to Kovacic algorithm to be an exclusive procedure (r, m) necessarily has to be in C 2 . Finally, the last case never occur because step two of Kovacic algorithm requires the quantity d = 1 2 (−m − 2q − 1) to be a non-negative integer which clearly is not, so we have to discard the family of equations with coefficients in M (2q+1,m) .…”

Section: Kovacic Algorithm Analysismentioning

confidence: 99%

“…In section 4 present some applications that involve the analysis of biconfluent Heun equation and doubly confluent Heun equation, as well Schrödinger Equations with Mie potentials (Laurent polynomial potentials, exponential potentials) and Inverse Square Root potentials, see [1,8,9]. Finally, our results allow us to state that there are no new algebraically solvable Laurent polynomial potentials for the Shcrödinger equation beyond those previously known (Corolary 4.1) corresponding to m = 2 and r = 0, 1, 2.…”

Section: Introductionmentioning

confidence: 99%

“…The space M (r,m) of monic Laurent polynomials of type (r, m) is an affine algebraic variety M (r,m) ≃ C * × C r+m−1 . The purpose of this paper is to classify Picard-Vessiot integrable equations in the family (1) and to study how their Liouvillian solutions depend algebraically on the coefficients of L(x) when it moves in the space M (r,m) . We thus introduce the spectral set.…”

Section: Introductionmentioning

confidence: 99%

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Liouvillian solutions for second order linear differential equations with polynomial coefficients

Acosta-Humánez

Blázquez-Sanz

Venegas-Gómez

2020

São Paulo J. Math. Sci.

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In this paper we present an algebraic study concerning the general second order linear differential equation with polynomial coefficients. By means of Kovacic's algorithm and asymptotic iteration method we find a degree independent algebraic description of the spectral set: the subset, in the parameter space, of Liouville integrable differential equations. For each fixed degree, we prove that the spectral set is a countable union of non accumulating algebraic varieties. This algebraic description of the spectral set allow us to bound the number of eigenvalues for algebraically quasi-solvable potentials in the Schrödinger equation.

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Liouvillian solutions for second order linear differential equations with Laurent polynomial coefficient

Acosta-Humánez

Blázquez-Sanz

Venegas-Gómez

2023

São Paulo J. Math. Sci.

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This paper is devoted to a complete parametric study of Liouvillian solutions of the general trace-free second order differential equation with a Laurent polynomial coefficient. This family of equations, for fixed orders at 0 and $$\infty$$ ∞ of the Laurent polynomial, is seen as an affine algebraic variety. We prove that the set of Picard-Vessiot integrable differential equations in the family is an enumerable union of algebraic subvarieties. We compute explicitly the algebraic equations of its components. We give some applications to well known subfamilies, such as the doubly confluent and biconfluent Heun equations, and to the theory of algebraically solvable potentials of Shrödinger equations. Also, as an auxiliary tool, we improve a previously known criterium for a second order linear differential equations to admit a polynomial solution.

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Generalized Lennard-Jones Potentials, SUSYQM and Differential Galois Theory

Cited by 4 publications

References 46 publications

From Poincaré to May: The Genesis of Discrete Dynamics

From Poincaré to May: The Genesis of Discrete Dynamics

Liouvillian solutions for second order linear differential equations with polynomial coefficients

Liouvillian solutions for second order linear differential equations with Laurent polynomial coefficient

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