Efficient perturbative framework for coupling of radiative and guided modes in nearly periodic surfaces

TL;DR

This paper introduces a semi-analytical framework that models the coupling between radiative and guided waves on nearly periodic surfaces, enabling better analysis of large-area metasurfaces with nonlocal effects.

Contribution

It combines local periodic approximation and spatial coupled-wave theory to model wave coupling, filling a gap in existing methods for slowly varying surfaces.

Findings

Framework accurately predicts wave coupling in slowly varying surfaces.

Validation against FDTD simulations shows increasing accuracy with slower surface variation.

Method enables efficient analysis of large-area metasurfaces with nonlocal effects.

Abstract

We present a semi-analytical framework for computing the coupling of radiative and guided waves in slowly varying (nearly uniform or nearly periodic) surfaces, which is especially relevant to the exploitation of nonlocal effects in large-area metasurfaces. Our framework bridges a gap in the theory of slowly varying surfaces: aside from brute-force numerical simulations, current approximate methods can model either guided or radiative waves, but cannot easily model their coupling. We solve this problem by combining two methods: the locally periodic approximation, which approximates radiative scattering by composing a set of periodic scattering problems, and spatial coupled-wave theory, which allows the perturbative modeling of guided waves using an eigenmode expansion. We derive our framework for both nearly uniform and nearly periodic surfaces, and we validate each case against brute-force finite-difference time-domain simulations, which show increasing agreement as the surface varies more slowly.