# Relaxed micromorphic broadband scattering for finite-size   meta-structures -- a detailed development

**Authors:** Alexios Aivaliotis (GEOMAS), Domenico Tallarico (GEOMAS),, Marco-Valerio D'Agostino, Ali Daouadji (GRG), Patrizio Neff, Angela Madeo, (GEOMAS)

arXiv: 1905.12297 · 2019-11-07

## TL;DR

This paper develops a semi-analytical approach using relaxed micromorphic models to accurately predict the broadband scattering behavior of finite-size elastic metamaterials, significantly reducing computational costs.

## Contribution

It introduces a boundary value problem setup within the relaxed micromorphic framework for finite structures, enabling efficient and accurate scattering analysis.

## Key findings

- Excellent agreement between semi-analytical and numerical results across a wide frequency range.
- Significant reduction in computational time using the relaxed micromorphic model.
- Reliable approximation of finite structure behavior by semi-infinite metamaterial analysis.

## Abstract

The conception of new metamaterials showing unorthodox behaviors with respect to elastic wavepropagation has become possible in recent years thanks to powerful dynamical homogenization techniques. Such methods effectively allow to describe the behavior of an infinite medium generated by periodically architectured base materials. Nevertheless, when it comes to the study of the scattering properties of finite-sized structures, dealing with the correct boundary conditions at the macroscopicscale becomes challenging. In this paper, we show how finite-domain boundary value problems canbe set-up in the framework of enriched continuum mechanics (relaxed micromorphic model) by imposing continuity of macroscopic displacement and of generalized traction when non-local effects areneglected.The case of a metamaterial slab of finite width is presented, its scattering properties are studied viaa semi-analytical solution of the relaxed micromorphic model and compared to numerical simulationsencoding all details of the selected microstructure. The reflection coefficient obtained via the twomethods is presented as a function of the frequency and of the direction of propagation of the incidentwave. We find excellent agreement for a large range of frequencies going from the long-wave limitto frequencies beyond the first band-gap and for angles of incidence ranging from normal to nearparallel incidence. The case of a semi-infinite metamaterial is also presented and is seen to be areliable measure of the average behavior of the finite metastructure. A tremendous gain in termsof computational time is obtained when using the relaxed micromorphic model for the study of theconsidered metastructure.

## Full text

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## Figures

49 figures with captions in the complete paper: https://tomesphere.com/paper/1905.12297/full.md

## References

42 references — full list in the complete paper: https://tomesphere.com/paper/1905.12297/full.md

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Source: https://tomesphere.com/paper/1905.12297