Correlation-Induced Sensitivity and Non-Hermitian Skin Effect of Quasiparticles

TL;DR

This paper demonstrates that non-Hermitian phenomena like the skin effect and spectral sensitivity can emerge in Hermitian many-body systems through quasiparticle interactions, using an extended SSH model analyzed with advanced computational methods.

Contribution

It reveals how non-Hermitian effects naturally arise in correlated fermionic systems via quasiparticle Green's functions, bridging Hermitian and non-Hermitian physics.

Findings

NH phenomena observed in quasiparticle properties of a Hermitian model.

Identification of NH skin effect and spectral sensitivity in an extended SSH model.

Use of exact diagonalization and Green's function methods to analyze the system.

Abstract

Non-Hermitian (NH) Hamiltonians have been shown to exhibit unique signatures, including the NH skin effect and an exponential spectral sensitivity with respect to boundary conditions. Here, we investigate as to what extent these remarkable phenomena, recently predicted and observed in a broad range of settings, may also occur in closed correlated fermionic systems that are governed by a Hermitian many-body Hamiltonian. There, an effectively NH quasiparticle description naturally arises in the Green's function formalism due to inter-particle scattering that represents an inherent source of dissipation. As a concrete platform we construct an extended interacting Su-Schrieffer-Heeger (SSH) model subject to varying boundary conditions, which we analyze using exact diagonalization and non-equilibrium Green's function methods. That way, we clearly identify the presence of the aforementioned NH phenomena in the quasi-particle properties of this Hermitian model system.