Disorder-Driven Exceptional Points and Concurrent Topological Phase Transitions in Non-Hermitian Lattice

Abstract: Exceptional point (EP) and topological phase transition (TPT) in non-Hermitian systems have recently garnered significant attention owing to their fundamental importance and potential applications in sensing and topological devices. Beyond the EP induced by non-reciprocal hopping, we show that random disorder can also drive the valence and conduction bands across EPs, even twice in the non-Hermitian regime. Remarkably, a TPT can occur concurrently with an EP as disorder strength increases. These disorder-driven EPs and concurrent TPTs are well captured by effective medium theory. The analysis reveals that their emergence results from the interplay between disorder-induced energy level renormalization and non-reciprocal hopping-induced inter-level coupling, which fundamentally restructures the spectral properties of the system. The phase diagram in the parameter space of non-reciprocal hopping and disorder strength identifies robust EP lines. Interestingly, two EP lines can emerge from the TPT point in the Hermitian limit. As non-reciprocal hopping increases, these lines split, with one aligning the TPT, leading to distinct disorder-induced EPs. Our results uncover a robust, disorder-driven mechanism for generating EPs and concurrent TPTs, offering a new direction for exploring non-Hermitian topological matter.