Integrable systems in magnetic fields: the generalized parabolic cylindrical case
Autoři
Kubů, O.; Marchesiello, A.; Šnobl, L.
Rok
2024
Publikováno
Journal of Physics A: Mathematical and Theoretical. 2024, 57(23), 1-21. ISSN 1751-8113.
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This article is a contribution to the classification of quadratically integrable systems with vector potentials whose integrals are of the nonstandard, nonseparable type. We focus on generalized parabolic cylindrical case, related to non-subgroup-type coordinates. We find three new systems, two with magnetic fields polynomial in Cartesian coordinates and one with unbounded exponential terms. The limit in the parameters of the integrals yields a new parabolic cylindrical system; the limit of vanishing magnetic fields leads to the free motion. This confirms the conjecture that non-subgroup type integrals can be related to separable systems only in a trivial manner.
Integrable systems of the ellipsoidal, paraboloidal and conical type with magnetic field
Autoři
Fazlul Hoque, M.; Marchesiello, A.; Šnobl, L.
Rok
2024
Publikováno
Journal of Physics A: Mathematical and Theoretical. 2024, 57(22), 1-31. ISSN 1751-8113.
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We construct integrable Hamiltonian systems with magnetic fields of the ellipsoidal, paraboloidal and conical type, i.e. systems that generalize natural Hamiltonians separating in the respective coordinate systems to include nonvanishing magnetic field. In the ellipsoidal and paraboloidal case each this classification results in three one-parameter families of systems, each involving one arbitrary function of a single variable and a parameter specifying the strength of the magnetic field of the given fully determined form. In the conical case the results are more involved, there are two one-parameter families like in the other cases and one class which is less restrictive and so far resists full classification.
Superintegrable families of magnetic monopoles with non-radial potential in curved background
Autoři
Marchesiello, A.; Reyes, D.; Šnobl, L.
Rok
2024
Publikováno
Journal of Geometry and Physics. 2024, 203 ISSN 1879-1662.
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We review some known results on the superintegrability of monopole systems in the three-dimensional (3D) Euclidean space and in the 3D generalized Taub-NUT spaces. We show that these results can be extended to certain curved backgrounds that, for suitable choice of the domain of the coordinates, can be related via conformal transformations to systems in Taub-NUT spaces. These include the multifold Kepler systems as special cases. The curvature of the space is not constant and depends on a rational parameter that is also related to the order of the integrals. New results on minimal superintegrability when the electrostatic potential depends on both radial and angular variables are also presented.
New classes of quadratically integrable systems in magnetic fields: The generalized cylindrical and spherical cases
Autoři
Kubů, O.; Marchesiello, A.; Šnobl, L.
Rok
2023
Publikováno
Annals of Physics. 2023, 451 ISSN 0003-4916.
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We study integrable and superintegrable systems with magnetic field possessing quadratic integrals of motion on the three-dimensional Euclidean space. In contrast with the case without vector potential, the corresponding integrals may no longer be connected to separation of variables in the Hamilton-Jacobi equation and can have more general leading order terms. We focus on two cases extending the physically relevant cylindrical -and spherical-type integrals. We find three new integrable sys-tems in the generalized cylindrical case but none in the spherical one. We conjecture that this is related to the presence, respec-tively absence, of maximal abelian Lie subalgebra of the three-dimensional Euclidean algebra generated by first order integrals in the limit of vanishing magnetic field. By investigating superin-tegrability, we find only one (minimally) superintegrable system among the integrable ones. It does not separate in any orthogonal coordinate system. This system provides a mathematical model of a helical undulator placed in an infinite solenoid. (c) 2023 Elsevier Inc. All rights reserved.
New classes of quadratically integrable systems with velocity dependent potentials: non-subgroup type cases
Autoři
Hoque, M.; Kubů, O.; Marchesiello, A.; Šnobl, L.
Rok
2023
Publikováno
EUROPEAN PHYSICAL JOURNAL PLUS. 2023, 138(9), 1-24. ISSN 2190-5444.
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We study quadratic integrability of systems with velocity dependent potentials in three-dimensional Euclidean space. Unlike in the case with only scalar potential, quadratic integrability with velocity dependent potentials does not imply separability in the configuration space. The leading order terms in the pairs of commuting integrals can either generalize or have no relation to the forms leading to separation in the absence of a vector potential. We call such pairs of integrals generalized, to distinguish them from the standard ones, which would correspond to separation. Here we focus on three cases of generalized non-subgroup type integrals, namely elliptic cylindrical, prolate/oblate spheroidal and circular parabolic integrals, together with one case not related to any coordinate system. We find two new integrable systems, non-separable in the configuration space, both with generalized elliptic cylindrical integrals. In the other cases, all systems found were already known and possess standard pairs of integrals. In the limit of vanishing vector potential, both systems reduce to free motion and therefore separate in every orthogonal coordinate system.
Pairs of commuting quadratic elements in the universal enveloping algebra of Euclidean algebra and integrals of motion
Autoři
Marchesiello, A.; Šnobl, L.
Rok
2022
Publikováno
Journal of Physics A: Mathematical and Theoretical. 2022, 55(14), ISSN 1751-8113.
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Motivated by the consideration of integrable systems in three spatial dimensions in Euclidean space with integrals quadratic in the momenta we classify three-dimensional Abelian subalgebras of quadratic elements in the universal enveloping algebra of the Euclidean algebra under the assumption that the Casimir invariant (p) over right arrow . (l) over right arrow vanishes in the relevant representation. We show by means of an explicit example that in the presence of magnetic field, i.e. terms linear in the momenta in the Hamiltonian, this classification allows for pairs of commuting integrals whose leading order terms cannot be written in the famous classical form of Makarov et al [17]. We consider limits simplifying the structure of the magnetic field in this example and corresponding reductions of integrals, demonstrating that singularities in the integrals may arise, forcing structural changes of the leading order terms.
Superintegrability of separable systems with magnetic field: the cylindrical case
Autoři
Kubů, O.; Marchesiello, A.; Šnobl, L.
Rok
2021
Publikováno
Journal of Physics A: Mathematical and Theoretical. 2021, 54(42), ISSN 1751-8113.
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We present a general method simplifying the search for additional integrals of motion of three dimensional systems with magnetic fields. The method is suitable for systems possessing at least one conserved canonical momentum in a suitable coordinates system. It reduces the problem either to consideration of lower dimensional systems or of particular constrained forms of the hypothetical integral. In particular, it is applicable to all separable systems in the Euclidean space since they are known to possess at least one cyclic coordinates when magnetic field is present. Next, we focus on systems which separate in the cylindrical coordinates. Using our method, we are able to classify all superintegrable systems of this kind under the assumption that all considered integrals are at most second order in the momenta. In addition to already known systems, several new minimally superintegrable systems are found and we show that no quadratically maximally superintegrable ones can exist. We also construct some examples of systems with higher order integrals.
Classical Superintegrable Systems in a Magnetic Field that Separate in Cartesian Coordinates
Autoři
Marchesiello, A.; Šnobl, L.
Rok
2020
Publikováno
Symmetry, Integrability and Geometry: Methods and Applications (SIGMA). 2020, 16 ISSN 1815-0659.
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We consider superintegrability in classical mechanics in the presence of magnetic fields. We focus on three-dimensional systems which are separable in Cartesian coordinates. We construct all possible minimally and maximally superintegrable systems in this class with additional integrals quadratic in the momenta. Together with the results of our previous paper [J. Phys. A: Math. Theor. 50 (2017), 245202, 24 pages], where one of the additional integrals was by assumption linear, we conclude the classification of three-dimensional quadratically minimally and maximally superintegrable systems separable in Cartesian coordinates. We also describe two particular methods for constructing superintegrable systems with higher-order integrals.
On the Detuned 2:4 Resonance
Autoři
Hanssmann, H.; Marchesiello, A.; Pucacco, G.
Rok
2020
Publikováno
Journal of nonlinear science. 2020, 30(6), 2513-2544. ISSN 0938-8974.
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We consider families of Hamiltonian systems in two degrees of freedom with an equilibrium in 1 : 2 resonance. Under detuning, this "Fermi resonance" typically leads to normal modes losing their stability through period-doubling bifurcations. For cubic potentials, this concerns the short axial orbits, and in galactic dynamics, the resulting stable periodic orbits are called "banana" orbits. Galactic potentials are symmetric with respect to the coordinate planes whence the potential-and the normal form-both have no cubic terms. This Z2xZ2 symmetry turns the 1 : 2 resonance into a higher-order resonance, and one therefore also speaks of the 2 : 4 resonance. In this paper, we study the 2 : 4 resonance in its own right, not restricted to natural Hamiltonian systems where H=T+V would consist of kinetic and (positional) potential energy. The short axial orbit then turns out to be dynamically stable everywhere except at a simultaneous bifurcation of banana and "anti-banana" orbits, while it is now the long axial orbit that loses and regains stability through two successive period-doubling bifurcations.
Bifurcations and monodromy of the axially symmetric 1:1:−2 resonance
Autoři
Efstathiou, K.; Hanßmann, H.; Marchesiello, A.
Rok
2019
Publikováno
Journal of Geometry and Physics. 2019, 146 ISSN 0393-0440.
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We consider integrable Hamiltonian systems in three degrees of freedom near an elliptic equilibrium in 1:1:−2 resonance. The integrability originates from averaging along the periodic motion of the quadratic part and an imposed rotational symmetry about the vertical axis. Introducing a detuning parameter we find a rich bifurcation diagram, containing three parabolas of Hamiltonian Hopf bifurcations that join at the origin. We describe the monodromy of the resulting ramified 3-torus bundle as variation of the detuning parameter lets the system pass through 1:1:−2 resonance
An Infinite Family of Maximally Superintegrable Systems in a Magnetic Field with Higher Order Integrals
Autoři
Marchesiello, A.; Šnobl, L.
Rok
2018
Publikováno
Symmetry, Integrability and Geometry: Methods and Applications (SIGMA). 2018, 14 ISSN 1815-0659.
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We construct an additional independent integral of motion for a class of three dimensional minimally superintegrable systems with constant magnetic field. This class was introduced in [J. Phys. A: Math. Theor. 50 (2017), 245202, 24 pages] and it is known to possess periodic closed orbits. In the present paper we demonstrate that it is maximally superintegrable. Depending on the values of the parameters of the system, the newly found integral can be of arbitrarily high polynomial order in momenta.
Spherical type integrable classical systems in a magnetic field
Autoři
Marchesiello, A.; Šnobl, L.; Winternitz, P.
Rok
2018
Publikováno
Journal of Physics A: Mathematical and Theoretical. 2018, 51(13), ISSN 1751-8113.
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We show that four classes of second order spherical type integrable classical systems in a magnetic field exist in the Euclidean space E-3, and construct the Hamiltonian and two second order integrals of motion in involution for each of them. For one of the classes the Hamiltonian depends on four arbitrary functions of one variable. This class contains the magnetic monopole as a special case. Two further classes have Hamiltonians depending on one arbitrary function of one variable and four or six constants, respectively. The magnetic field in these cases is radial. The remaining system corresponds to a constant magnetic field and the Hamiltonian depends on two constants. Questions of superintegrability-i. e. the existence of further integrals-are discussed.
Superintegrable 3D systems in a magnetic field corresponding to Cartesian separation of variables
Autoři
Marchesiello, A.; Šnobl, L.
Rok
2017
Publikováno
Journal of Physics A: Mathematical and Theoretical. 2017, 50(24), ISSN 1751-8113.
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We consider three dimensional superintegrable systems in a magnetic field. We study the class of such systems which separate in Cartesian coordinates in the limit when the magnetic field vanishes, i.e. possess two second order integrals of motion of the 'Cartesian type'. For such systems we look for additional integrals up to second order in momenta which make these systems minimally or maximally superintegrable and construct their polynomial algebras of integrals and their trajectories. We observe that the structure of the leading order terms of the Cartesian type integrals should be considered in a more general form than for the case without magnetic field.