Topological Phase Transition and Eigenstates Localization in a Generalized Non-Hermitian Su-Schrieffer-Heeger Model

The topological properties of a generalized non-Hermitian Su-Schrieffer-Heeger model are investigated and it is demonstrated that the non-Hermitian phase transition and the non-Hermitian skin effect can be induced by intra-cell asymmetric coupling under open boundary conditions. Through investigating and calculating the non-Hermitian winding number with generalized Brillouin zone theory, it is found that the present non-Hermitian system has an exact bulk-boundary correspondence relationship. Meanwhile, the non-Hermitian winding number is used to characterize the non-Hermitian phase transition and determine the phase transition boundary, and it is found that the non-Hermitian phase transition is not completely induced by the asymmetric coupling strength. By means of the mean inverse participation ratio, the factors that affect the eigenstates localization are shown and it is revealed that large system size or large asymmetric coupling strength can leave the system in the localized state. Additionally, it is found that for the asymmetric coupling strength and the system size, the eigenstates localization is much more sensitive to the asymmetric coupling strength.