Linear coupling between lightwaves in metamaterials enables lossless artificial magnetism

TL;DR

This paper demonstrates that engineered metamaterials can enable linear, lossless power exchange between lightwaves, leading to artificial magnetism and new optical functionalities without nonlinear effects.

Contribution

It introduces a novel blueprint for magnetic metamaterials that allows linear, coherent power transfer between lightwaves, overcoming traditional limitations of linear media.

Findings

Linear coupling enables lossless power exchange between lightwaves.

Metamaterials can be engineered for active power flow without nonlinearity.

Potential applications include advanced optical devices and artificial magnetism.

Abstract

A well-known principle in optical physics states that power can never be exchanged between two light waves propagating inside a homogeneous medium when the medium response is strictly linear. Power exchange between light waves usually occurs with the aid of nonlinearity. A typical example is nonlinear optical parametric amplification where net energy can flow from a high-frequency (high-energy) light wave (pump) to a lower-frequency signal wave, leading to amplification of the signal wave. Here, we show that this limitation of ordinary media can be overcome using suitably engineered metamaterials, which in the recent past have enabled a variety of extraordinary applications, unattainable using conventional materials, such as perfect lenses, invisibility cloaks and trapped rainbows. We introduce a blueprint for magnetic metamaterials that enables, in a totally linear fashion, coherent and constructive active power flow from one light wave to another (second) light wave.