Point-gap bound states in non-Hermitian systems

In this paper, we systematically investigate impurity-induced bound states in one-dimensional non-Hermitian systems. By establishing the relationship between bound-state energy and the requisite impurity potential, we conveniently construct an impurity potential diagram corresponding to point gaps. This diagram indicates both the minimal impurity potential required to generate bound states within each point gap and the distribution of bound states across these point gaps for a given impurity potential. From this, we reveal that a finite impurity potential is required to generate bound states in the absence of Bloch saddle points; otherwise, even a negligible impurity potential can yield bound states. Additionally, we show that bound states in point gaps with nonzero spectral winding numbers are sensitive to boundary conditions and abruptly shift to the edges upon opening the boundaries, signifying the bulk-boundary correspondence in point-gap topology.

Automated summary

In this paper, we systematically investigate impurity-induced bound states in one-dimensional non-Hermitian systems. By constructing an impurity potential diagram, the minimal impurity potential required to generate bound states and the distribution of bound states are revealed. It is found that a finite impurity potential is required to generate bound states in the absence of Bloch saddle points.