Quantum noise and mode nonorthogonality in nonhermitian PT-symmetric optical resonators

TL;DR

This paper analyzes quantum noise and mode nonorthogonality in PT-symmetric optical resonators, showing how these factors influence emission lineshapes and relate to spontaneous symmetry breaking near exceptional points.

Contribution

It provides a frequency-resolved analysis of output radiation intensity in PT-symmetric resonators, incorporating quantum noise and mode nonorthogonality, including non-symmetric configurations.

Findings

Emission lineshape varies with resonance overlap and symmetry breaking

Mode nonorthogonality affects excess noise and radiation intensity

Distinct behaviors near exceptional points and in weakly amplifying regimes

Abstract

PT-symmetric optical resonators combine absorbing regions with active, amplifying regions. The latter are the source of radiation generated via spontaneous and stimulated emission, which embodies quantum noise and can result in lasing. We calculate the frequency-resolved output radiation intensity of such systems and relate it to a suitable measure of excess noise and mode nonorthogonality. The lineshape differs depending on whether the emission lines are isolated (as for weakly amplifying, almost hermitian systems) or overlapping (as for the almost degenerate resonances in the vicinity of exceptional points associated to spontaneous PT-symmetry breaking). The calculations are carried out in the scattering input-output formalism, and are illustrated for a quasi one-dimensional resonator set-up. In our derivations we also allow for the more general case of a resonator in which the amplifying and absorbing regions are not related by symmetry.