Non-Hermitian transparency and one-way transport in low-dimensional lattices by an imaginary gauge field

TL;DR

This paper investigates one-dimensional non-Hermitian lattices with an imaginary gauge field, revealing a novel one-way transparency phenomenon where spectral transmission becomes perfect despite disorder, enabled by evanescent reflected waves.

Contribution

It introduces the concept of non-Hermitian transparency in 1D lattices with an imaginary gauge field, demonstrating robust one-way transport and spectral mapping in the complex plane.

Findings

Spectral transmittance approaches one at large gauge fields despite disorder.

Reflected waves are evanescent, preventing backscattering.

Double heterostructures enable asymmetric wave transmission.

Abstract

Unidirectional and robust transport is generally observed at the edge of two- or three-dimensional quantum Hall and topological insulator systems. A hallmark of these systems is topological protection, i.e. the existence of propagative edge states that cannot be scattered by imperfections or disorder in the system. A different and less explored form of robust transport arises in non-Hermitian systems in the presence of an {\it imaginary} gauge field. As compared to topologically-protected transport in quantum Hall and topological insulator systems, robust non-Hermitian transport can be observed in {\it lower} dimensional (i.e. one dimensional) systems. In this work the transport properties of one-dimensional tight-binding lattices with an imaginary gauge field are theoretically investigated, and the physical mechanism underlying robust one-way transport is highlighted. Back scattering is here forbidden because reflected waves are evanescent rather than propagative. Remarkably, the spectral transmission of the non-Hermitian lattice is shown to be mapped into the one of the corresponding Hermitian lattice, i.e. without the gauge field, {\it but} computed in the complex plane. In particular, at large values of the gauge field the spectral transmittance becomes equal to one, even in the presence of disorder or lattice imperfections. This phenomenon can be referred to as {\it one-way non-Hermitian transparency}. Robust one-way transport can be also realized in a more realistic setting, namely in heterostructure systems, in which a non-Hermitian disordered lattice is embedded between two homogeneous Hermitian lattices. Such a double heterostructure realizes asymmetric (non-reciprocal) wave transmission. A physical implementation of non-Hermtian transparency, based on light transport in a chain of optical microring resonators, is suggested.