PT-Symmetry and Supersymmetry: Interconnection of Broken and Unbroken Phases

TL;DR

This paper investigates the relationship between PT-symmetry and supersymmetry in optical systems using complex Scarf potentials, revealing phase transitions, supersymmetry breaking, and connections to integrable equations.

Contribution

It uncovers how supersymmetry and PT-symmetry interconnect in complex optical potentials, highlighting phase transitions and parametric behaviors with novel theoretical insights.

Findings

Transition from unbroken to broken PT-symmetry phases near exceptional points.

Spontaneous supersymmetry breaking occurs in the PT-symmetric phase.

Zero-width resonances at integral potential parameters.

Abstract

The broken and unbroken phases of PT and supersymmetry in optical systems are explored for a complex refractive index profile in the form of a Scarf potential, under the framework of supersymmetric quantum mechanics. The transition from unbroken to the broken phases of PT-symmetry, with the merger of eigenfunctions near the exceptional point is found to arise from two distinct realizations of the potential, originating from the underlying supersymmetry. Interestingly, in PT-symmetric phase, spontaneous breaking of supersymmetry occurs in a parametric domain, possessing non-trivial shape invariances, under reparametrization to yield the corresponding energy spectra. One also observes a parametric bifurcation behaviour in this domain. Unlike the real Scarf potential, in PT-symmetric phase, a connection between complex isospectral superpotentials and modified KdV equation occurs, only with certain restrictive parametric conditions. In the broken PT-symmetry phase, supersymmetry is found to be intact in the entire parameter domain yielding the complex energy spectra, with zero-width resonance occurring at integral values of a potential parameter.