Enantiosensitive positions of exceptional points in open chiral systems

Abstract: Exceptional points are remarkable features of open quantum systems, such as photo-ionizing or photo-dissociating molecules, amplified or dissipated light states in photonic structures, and many others. These points mark spectral degeneracies in a system's parameter space where the eigenstates become non-orthogonal, enabling precise control over decay rates, topological transitions in parity-time (PT)-symmetric systems, or boosting the system's sensitivity to external stimuli. Here we show that exceptional points can be enantiosenstive, enabling a new type of control over topological and chiral properties of non-Hermitian open chiral systems. We apply the concept of enantio-sensitive exceptional points to demonstrate a broad range of phenomena, from enantiosensitive topological population transfer, to lifetime branching in resonant photo-decay of chiral molecules, to enhanced chiral sensing in optical fibers. Our results combine high enantiosensitivity with topological robustness in chiral discrimination and separation, paving the way for new approaches in the control of non-Hermitian and chiral phenomena.