Multiband homogenization of metamaterials in real-space: Higher-order nonlocal models and scattering at external surfaces

TL;DR

This paper develops a higher-order dynamic homogenization method for metamaterials, enabling accurate modeling of wave scattering and nonlocal effects across multiple frequency bands and complex geometries.

Contribution

It introduces a novel higher-order homogenized equation that captures nonlocal spatial and temporal effects in metamaterials across multiple bands, improving accuracy and computational efficiency.

Findings

Homogenized equations match exact solutions well across frequencies.

Boundary conditions predict wave scattering accurately.

Model suggests nonlocality emerges with multiple bands.

Abstract

This work develops a dynamic homogenization approach for metamaterials. It finds an approximate macroscopic homogenized equation with constant coefficients posed in space and time; however, the resulting homogenized equation is higher order in space and time. The homogenized equation can be used to solve initial-boundary-value problems posed on arbitrary non-periodic macroscale geometries with macroscopic heterogeneity, such as bodies composed of several different metamaterials or with external boundaries. First, considering a single band, the higher-order space derivatives lead to additional continuity conditions at the boundary between a homogeneous material and a metamaterial. These provide predictions of wave scattering in 1-d and 2-d that match well with the exact fine-scale solution; compared to alternative approaches, they provide a single equation that is valid over a broad range of frequencies, are easy to apply, and are much faster to compute. Next, the setting of two bands with a bandgap is considered. The homogenized equation has also higher-order time derivatives. Notably, the homogenized model provides a single equation that is valid over both bands and the bandgap. The continuity conditions are applied to wave scattering at a boundary, and show good agreement with the exact fine-scale solution. Using that the order of the highest time derivative is proportional to the number of bands considered, a nonlocal-in-time structure is conjectured for the homogenized equation in the limit of infinite bands. This suggests that homogenizing over finer length and time scales -- with the temporal homogenization being carried out through the consideration of higher bands in the dispersion relation -- is a mechanism for the emergence of macroscopic spatial and temporal nonlocality, with the extent of temporal nonlocality being related to the number of bands considered.