New classes of quadratically integrable systems in magnetic fields: The generalized cylindrical and spherical cases

“…The results presented here complement the results of [31]. Therein classes from theorem 1 were considered which generalize the structure of integrals characterizing physically relevant cases of cylindrical and spherical separability.…”

“…One of the observations coming from the results presented here and in [31] is that for almost all nonstandard type systems discovered so far (except the system (3.48) in [31]), i.e. those not reducing to the leading order structure of its integrals corresponding to an orthogonal separation, one of the integrals reduces to a first order one.…”

“…However, while investigating systems with Cartesian type integrals [28][29][30] it was observed that in the presence of magnetic fields, the leading order structure of the integrals may not always reduce to the classes relevant in the context of purely scalar potentials. This observation was further elaborated on in [1] where the classification of the leading order terms as admitted by the algebraic structure of the Euclidean algebra was performed and in [31] where the systems with generalized cylindrical and spherical type integrals were classified, leading to several new classes of quadratically integrable systems with magnetic fields. In the present paper we focus on one class of commuting elements in the universal enveloping algebra of the Euclidean algebra, namely class (i) of [1] and classify all systems with the corresponding integrals.…”

Family of nonstandard integrable and superintegrable classical Hamiltonian systems in non-vanishing magnetic fields

“…The results presented here complement the results of [31]. Therein classes from theorem 1 were considered which generalize the structure of integrals characterizing physically relevant cases of cylindrical and spherical separability.…”

“…One of the observations coming from the results presented here and in [31] is that for almost all nonstandard type systems discovered so far (except the system (3.48) in [31]), i.e. those not reducing to the leading order structure of its integrals corresponding to an orthogonal separation, one of the integrals reduces to a first order one.…”

“…However, while investigating systems with Cartesian type integrals [28][29][30] it was observed that in the presence of magnetic fields, the leading order structure of the integrals may not always reduce to the classes relevant in the context of purely scalar potentials. This observation was further elaborated on in [1] where the classification of the leading order terms as admitted by the algebraic structure of the Euclidean algebra was performed and in [31] where the systems with generalized cylindrical and spherical type integrals were classified, leading to several new classes of quadratically integrable systems with magnetic fields. In the present paper we focus on one class of commuting elements in the universal enveloping algebra of the Euclidean algebra, namely class (i) of [1] and classify all systems with the corresponding integrals.…”

Family of nonstandard integrable and superintegrable classical Hamiltonian systems in non-vanishing magnetic fields

“…Afterwards, we have searched for new systems in the respective classes. In [27] we have classified systems with integrals generalizing the cylindrical and spherical case, which together with the analysis of the corresponding standard cases in [16,18] completely exhaust these two physically very important cases. In [28] we constructed all integrable systems of one nonstandard case of [26] (case (i) therein), leading to one family of solutions depending on 5 parameters.…”

Integrable systems of the ellipsoidal, paraboloidal and conical type with magnetic field

“…We call such integrals nonstandard. To confirm that these classes are not empty, we have to consider the lower order terms in momenta as well in each class; we have done it for some of them [11,12,16]. Quite a few nonstandard integrable systems were found, though a complete study of all classes has not been achieved yet.…”

Integrable systems in magnetic fields: the generalized parabolic cylindrical case