Generalized quantum Zernike Hamiltonians: Polynomial Higgs-type algebras and algebraic derivation of the spectrum

Abstract

We consider the quantum analog of the generalized Zernike systems given by the Hamiltonian: HN =p12+p22+Σk=1N γk (q1 p1+q2 p2)k , with canonical operators qi,\, pi and arbitrary coefficients γk. This two-dimensional quantum model, besides the conservation of the angular momentum, exhibits higher-order integrals of motion within the enveloping algebra of the Heisenberg algebra in two dimensions. By constructing suitable combinations of these integrals, we uncover a polynomial Higgs-type symmetry algebra that, through an appropriate change of basis, gives rise to a deformed oscillator algebra. The associated structure function Φ is shown to factorize into two commuting components Φ=Φ1 Φ2. This framework enables an algebraic determination of the possible energy spectra of the model for the cases 1 N 5, the case N=1 being canonically equivalent to the harmonic oscillator. Based on these findings, we propose two conjectures which generalize the results for all N 1 and any value of the coefficients γk. In addition, all of these results can be interpreted as higher-order superintegrable perturbations of the original quantum Zernike system corresponding to N=2, which are also analyzed and applied to the isotropic oscillator on the sphere, hyperbolic and Euclidean spaces