Excitation of forward and backward surface waves in a negative-index metamaterial

TL;DR

This paper investigates how resonant excitation of forward and backward surface waves in negative-index metamaterials affects beam transmission and reflection, demonstrating their propagation and energy-trapping capabilities through FDTD simulations.

Contribution

It provides the first detailed numerical demonstration of resonant excitation and propagation of both forward and backward surface waves in negative-index metamaterials.

Findings

High-amplitude transmitted and reflected beams observed.

Clear propagation of surface waves confirmed by simulations.

Potential applications in optical and photonic devices.

Abstract

We study beam transmission and refection resulting from the resonant excitation of forward and backward surface waves in a metamaterial. We predict that exciting these waves at an interface this medium and free space led to transmitted and reflected beams with high amplitudes. The FDTD simulated results demonstrate clearly propagation of these waves and their energy-trapping ability as described by theory. The resonant coupling of the refracted waves and reflected waves at the first interface led to the excitation of the backward surface waves. The forward surface waves transfer incoming energy in the direction of incidence and the backward surface transfer incoming energy in a direction opposite to the direction of incidence (i.e. negative direction). More also, the parameters used in these simulations were carefully chosen to minimize the effects of interference between the incident and the reflected beams earlier reported. In overall, these numerically simulated results clearly demonstrate the propagation of these waves and may serve as numerical approximations to what might be observed in experimental setups. Putting this simply, they may find applications in optical and photonic devices involving enhancing beam transmission and reflection using negative-index metamaterial.