Active nonreciprocal cloaking for pseudo-Hermitian magnons

TL;DR

This paper demonstrates electrically controlled, non-reciprocal magnon cloaking using PT-symmetry, enabling unidirectional invisibility and potential applications in magnonic signal processing.

Contribution

It introduces a novel method for active, electrically tunable magnon cloaking based on PT-symmetry and pseudo-Hermitian dynamics in magnonic channels.

Findings

Achieved unidirectional invisibility at exceptional points (EPs).

Extended invisibility in periodic PT-symmetric regions.

Marginal damping confirms experimental feasibility.

Abstract

Cloaking has important applications but entails sophisticated control of signal propagation and scattering characteristics. Here, we show that invisibility for magnon signals is achievable in a non-reciprocal and electrically controlled way by engineering the magnonic channels such that they exhibit PT-symmetry. This is accomplished by attaching current-carrying heavy metal contacts to the magnon waveguides and exerting fields from an attached bias layer. Tuning the current density in the metal layer, the magnons in this setup experience electrically controlled, compensated gain and loss due to spin-orbit torque which renders the setup PT-symmetric. The magnon dynamics is then shown to be pseudo-Hermitian with exceptional points (EPs) determined actively by an external electric field. We analyze the magnon scattering from single and periodic PT-symmetric regions and identify the conditions necessary for the formation of unidirectional invisibility which can be steered by specific combinations of bias layers and current amplitudes in the heavy metal as to reach the EP. The unidirectional invisibility at EP is found to be extended for a periodic PT-symmetric region. Intrinsic damping on PT-symmetric unidirectional invisibility is shown to be marginal confirming the experimental feasibility. It is shown how the unidirectional magnons can be utilized to amplify and generate magnonic orbital angular momentum states in coupled magnetic rings demonstrating a new path for manipulating magnon propagation and processing.