Puiseux series about exceptional singularities dictated by symmetry-allowed Hessenberg forms of perturbation matrices

Abstract

We develop a systematic framework for determining the nature of exceptional points of n th order (EPns) in non-Hermitian (NH) systems, represented by complex square matrices. By expressing symmetry-preserving perturbations in the Jordan-normal basis of the defective matrix at an EPn, we show that the upper-k Hessenberg structure of the perturbation directly dictates the leading-order eigenvalue- and eigenvector-splitting to be ε1/k, when expanded in a Puiseux series. Applying this to three-band NH models invariant under parity (P), charge-conjugation (C), or parity-time-reversal (PT), we find that EP3s in P- and C-symmetric systems are restricted to at most ε1/2 branch points, while PT-symmetric systems generically support EP3s with the strongest possible singularities (viz. ε1/3). We illustrate these results with concrete three-dimensional models in which exceptional curves and surfaces emerge. We further show that fine-tuned perturbations can suppress the leading-order branch point to a less-singular splitting, which have implications for designing direction-dependent EP-based sensors. The appendix extends the analysis to four-band C- and P-symmetric models, establishing the existence of EP4s with ε1/4 singularities.

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