Controllable Unidirectional Transport and Light Trapping Using a One-dimensional Lattice with Non-Hermitian Coupling

Overview

Journal Sci Rep

Specialty Science

Date 2020 Jan 26

PMID 31980668

Authors

Lei Du

Yan Zhang

Jin-Hui Wu

Affiliations

Soon will be listed here.

Abstract

We propose a one-dimensional tight-binding lattice with special non-Hermitian coupling, the imaginary part of which is modulated by an effective Peierls phase arising from the synthetic magnetic field. Such a non-Hermitian lattice supports robust unidirectional transport that is reflectionless and immune to defects; it thus can serve as a frequency-selectable light filter. To achieve more applications, we further construct two well-designed structures involving this lattice, namely a heterostructure and a sandwich structure. An optical diode can be realized using the heterostructure, while tunable light trapping and reversal can be realized through phase modulations on the sandwich structure. The results in this paper may not only open up a new path for unconventional light transport but also have potential applications for optical communication.

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