Exactly solvable model behind Bose-Hubbard dimers, Ince-Gauss beams, and aberrated optical cavities

TL;DR

This paper introduces the Ince oscillator, an exactly solvable model unifying optical cavity modes and Bose-Hubbard dimers, revealing topological transitions driven by system-specific parameters.

Contribution

It presents the Ince oscillator as a new analytical model linking optical and quantum many-body systems, highlighting their topological transition mechanisms.

Findings

Ince-Gauss beams are supported in aberrated optical cavities.

The Ince oscillator describes a topological transition in both optical and superfluid systems.

Different physical parameters drive the transition in optical and quantum cases.

Abstract

By studying the effects of quadratic anisotropy and quartic perturbations on the two-dimensional harmonic oscillator, one arrives at a simple model termed here the Ince oscillator, whose analytic solutions are given in terms of Ince polynomials. This one model unifies diverse physical systems, including aberrated optical cavities that are shown to support Ince-Gauss beams as their modes, and the two-mode Bose-Hubbard dimer describing two coupled superfluids. The Ince oscillator model describes a topological transition which can have very different origins: in the optical case, which is fundamentally linear, it is driven by the ratio of astigmatic to spherical mirror aberrations, whereas in the superfluid case it is driven by the ratio of particle tunneling to interparticle interactions and corresponds to macroscopic quantum self trapping.