Linear level repulsions near exceptional points of non-Hermitian systems

Abstract

The nearest-neighbor level-spacing distributions are a fundamental quantity of disordered systems and universal. It is well-known that extended and localized states of random Hermitian systems follow the Wigner-Dyson and the Poison distributions, respectively, while the Ginibre distributions describe random non-Hermitian systems with complex eigenvalues. However, the level distribution of systems of neither Hermitian nor non-Hermitian with full complex eigenvalues is still unknown. Here we show a new class of universal level distributions in the vicinity of exceptional points of non-Hermitian Hamiltonians. Two universal distribution functions, PSP(s) for the symmetry-preserved phase and PSB(s) for the symmetry-broken phase, are needed to describe the nearest-neighbor level-spacing distributions near exceptional points. Surprisingly, both PSP(s) and PSB(s) are proportional to s for small s, or a linear level repulsion, in contrast to the cubic level repulsions of the Ginibre ensembles. For non-Hermitian disordered tight-binding Hamiltonians, PSP(s) and PSB(s) can be well described by PSP(SB)(s)=c1s[-c2sα] in the thermodynamic limit (of infinite systems) with a constant α that depends on the localization nature of states at exceptional points.