A unified framework for exceptional point pairs in non-Hermitian two-level systems (2509.09129v1)

Abstract: Exceptional points (EPs) in non-Hermitian systems are branch singularities where eigenvalues and eigenvectors simultaneously coalesce, leading to rich topological phenomena beyond those in Hermitian systems. In this work, we systematically investigate the interplay between eigenenergy braiding and Berry phase accumulation in two-level non-Hermitian systems hosting pairs of EPs. EP pairs are classified into four distinct classes according to the vorticity of eigenenergies, the Berry phase accumulated during encircling, and the eigenstate projection onto a basis state. Their associated topological structures are analyzed using effective two-level models. These classifications are further substantiated by numerical simulations in optical microcavities with three scatterers, where EPs emerge in the complex frequency spectrum. By encircling different EP pairs in parameter space, we demonstrate that the resulting topological features such as trivial or non-trivial braiding and Berry phase accumulation are directly linked to the vorticity structure and eigenmode evolution. In particular, we show that the eigenstate projection onto a basis state near EPs manifests as chiral optical modes in microcavities, providing an experimentally accessible signature of the underlying topological structure. Our results provide a unified framework for understanding multi-EP topology and offer practical pathways toward their realization and control in photonic systems.