Asymmetric transmission in planar chiral split-ring metamaterials: Microscopic Lorentz-theory approach

TL;DR

This paper uses Lorentz theory to analyze how planar chiral split-ring metamaterials exhibit asymmetric transmission of circularly polarized light, depending on their geometry and symmetry properties.

Contribution

It introduces a microscopic Lorentz-theory approach to calculate the effective permittivity tensor of planar chiral metamaterials, revealing their asymmetric optical transmission behavior.

Findings

Asymmetric transmission depends on split-ring geometry.

The permittivity tensor becomes elliptically dichroic with broken mirror symmetry.

Transmission differs for right- and left-handed circular polarization.

Abstract

The electronic Lorentz theory is employed to determine the electromagnetic response of planar split-ring metamaterials. Starting from the dynamics of individual free carriers, the effective permittivity tensor of the metamaterial is calculated. Whenever the split ring lacks in-plane mirror symmetry, the corresponding permittivity tensor has a crystallographic structure of an elliptically dichroic medium, and the metamaterial exhibits optical properties of planar chiral structures. Its transmission spectra are different for right-handed vs. left-handed circular polarization of the incident wave, so the structure changes its transmittance when the direction of incidence is reversed. The magnitude of this change is shown to be related to the geometric parameters of the split ring. The proposed approach can be straightforwardly generalized to a wide variety of metal-dielectric metamaterial geometries.