Controlling asymmetric absorption of metasurfaces via non-Hermitian doping

TL;DR

This paper introduces non-Hermitian doping in metasurfaces to control asymmetric light absorption, enabling reconfigurable optical devices with tunable unidirectional properties demonstrated at microwave frequencies.

Contribution

It presents a novel approach of non-Hermitian doping to achieve tunable asymmetric absorption in metasurfaces, including experimental validation and extension to one-sided amplification.

Findings

Asymmetric absorption reaches unity at the exceptional point.

Experimental demonstration at microwave frequencies confirms the concept.

Extension to one-sided amplification in two-dimensional systems.

Abstract

Metasurfaces based on subwavelength resonators enable novel ways to manipulate the flow of light at optical interfaces. In pursuit of multifunctional or reconfigurable metadevices, efficient tuning of macroscopic performance with little structural/material variation remains a challenge. Here, we put forward the concept of non-Hermitian doping in metasurfaces, showing that an ordinary retroreflector can be switched to asymmetric one by introducing absorptive defects in local regions. The asymmetric absorption performance begins with zero at the Hermitian state, gradually increases under non-Hermitian doping, and reaches the maximum of unity at the exceptional point. This effect is experimentally demonstrated at microwave frequencies via the observation of asymmetric near-field distribution and far-field scattering properties and from a planar metasurface. Furthermore, while importing local gain constituents in conventional retroreflector, it can be tuned to an extremely asymmetric one-side amplifier, extending unidirectional amplification from one-dimensional waveguide to two-dimensional scattering systems. The proposed methodology provides an alternative pathway for engineering electromagnetic metadevices and systems with small perturbations. Introduction