Generalized Petermann factor of non-Hermitian systems at exceptional points

TL;DR

This paper extends the concept of the Petermann factor to exceptional points in non-Hermitian systems, providing geometric interpretations and demonstrating its impact on system response and spectral behavior.

Contribution

It introduces a generalized Petermann factor at exceptional points, with geometric insights and a physical example demonstrating improved spectral response analysis.

Findings

The EP Petermann factor diverges at degeneracies.

Two geometric interpretations of the EP PF are provided.

A microring system example shows enhanced response prediction.

Abstract

The nonorthogonality of modes in open systems significantly modifies their resonant response, resulting in quantitative and qualitative deviations from Breit-Wigner resonance relations. For isolated resonances with a Lorentzian lineshape, the deviations amount to an enhancement of the resonance linewidth by the Petermann factor (PF), given by the overlap of left and right eigenmodes of the underlying effectively non-Hermitian Hamiltonian. The PF diverges at exceptional points (EPs), where resonance frequencies degenerate, and right and left eigenmodes are orthogonal to each other. This divergence signifies a qualitative departure from a Lorentzian lineshape, which has gained recent attention. In this work, we extend this concept to EPs, and describe how this EP PF manifests in a variety of physical scenarios. Firstly, we identify this PF in physical terms as an enhancement of the response of a system to external or parametric perturbations. Utilizing two natural orthogonally projected reference systems based on the right and left eigenvectors, we show that each choice carries a precise geometric interpretation that naturally extends the notion of the PF for isolated resonances to EPs. The two choices can be combined into an overall EP PF, which again can be expressed in purely geometric terms. Secondly, we illuminate the geometric mechanisms that determine the size of the EP PF, by considering the role of modes participating in the degeneracy and those that remain spectrally separated. Thirdly, we design a system to study the EP PF in a specific physical setup, consisting of two microrings coupled to a waveguide with embedded semitransparent mirrors. This example shows our approach yields a more accurate spectral response strength than conventional truncation. These results complete the description of systems at EPs in the same way as the original PF does for isolated resonances.