Interaction-Induced Second-Order Skin Effect

TL;DR

This paper demonstrates an interaction-induced second-order non-Hermitian skin effect in a two-dimensional bosonic system, where many-body interactions lead to corner-localized skin modes absent in non-interacting cases.

Contribution

It introduces the first example of a many-body interaction-induced second-order skin effect in a 2D non-Hermitian bosonic lattice system.

Findings

Interaction induces corner skin modes for doublon states

Number of skin modes scales linearly with system size

Skin modes are localized at lattice corners

Abstract

In contrast to the conventional (first-order) non-Hermitian skin effect (NHSE) in a $d$-dimensional system with linear size $L$, the $n$th-order (higher-order) NHSE is characterized by skin modes localized at lower-dimensional boundaries of dimension $(d-n)$. The total number of these modes scales linearly with the system size $L$. Significant progress has been made in understanding higher-order NHSE in non-interacting systems. In this work, we demonstrate the many-body interaction induced second-order skin effect in a two-dimensional non-Hermitian bosonic system. Specifically, we construct a square lattice that incorporates nonreciprocal single-boson hopping, onsite many-body interactions and two-boson pairing hopping. In the absence of interactions, no second-order NHSE is observed. However, with the inclusion of interactions, we identify interaction-induced skin modes for in-gap doublon states (i.e., bound pairs of bosons) localized at the corners of the lattice, while the bulk doublon states remain extended. These corner-localized skin modes arise from the interplay between interaction-induced edge states, localized along one-dimensional boundaries, and the nonreciprocal hopping along these boundaries. Furthermore, the number of corner skin modes scales linearly with the system size, confirming the presence of second-order NHSE in this interacting system. Our findings introduce a novel approach to realizing higher-order skin effects by leveraging interactions.