Drift-induced Unidirectional Graphene Plasmons

TL;DR

This paper proposes a novel method to achieve unidirectional, nonreciprocal surface plasmon propagation on graphene using a drift electric current, enabling robust, long-range, one-way light flow in integrated photonic systems.

Contribution

It introduces a theoretical model demonstrating that drift-biased graphene can support tunable, one-way plasmon propagation with immunity to backscattering, advancing nonreciprocal photonic device design.

Findings

Graphene with drift current exhibits strong nonreciprocal response.

Surface plasmon polaritons can propagate unidirectionally and resist backscattering.

Propagation length of graphene plasmons can be increased by over 100%.

Abstract

Nonreciprocal photonic devices enable "one-way" light flows and are essential building blocks of optical systems. Here, we investigate an alternative paradigm to break reciprocity and achieve unidirectional subwavelength light propagation fully compatible with modern all-photonic highly-integrated systems. In agreement with a few recent studies, our theoretical model predicts that a graphene sheet biased with a drift electric current has a strong nonreciprocal tunable response. Strikingly, we find that the propagation of the surface plasmon polaritons can be effectively "one-way" and may be largely immune to the backscattering from defects and obstacles. Furthermore, the drift-current biasing may boost the propagation length of the graphene plasmons by more than 100%. Our findings open new inroads in nonreciprocal photonics and offer a new opportunity to control the flow of light with one-atom thick nonreciprocal devices.