Reflection and transmission of elastic waves at interfaces embedded in non-local band-gap metamaterials: a comprehensive study via the relaxed micromorphic model

TL;DR

This study develops a theoretical framework for analyzing elastic wave reflection and transmission at interfaces involving non-local band-gap metamaterials using the relaxed micromorphic model, revealing unique wave behaviors and potential for novel metastructures.

Contribution

It introduces jump conditions for non-dissipative micromorphic media and explores their impact on wave reflection, transmission, and band-gap phenomena at interfaces, advancing the modeling of complex metamaterials.

Findings

Complete reflection occurs within band-gaps in relaxed micromorphic media.

Reflective patterns are significantly altered in Mindlin's micromorphic media.

The work suggests methods for indirect measurement of material coefficients.

Abstract

In this paper we derive, by means of a suitable least action principle, the duality jump conditions to be imposed at surfaces of discontinuity of the material properties in non-dissipative, linear-elastic, isotropic, Mindlin's and relaxed micromorphic media, respectively. The introduced theoretical framework allows the transparent set-up of different types of micro-macro connections which are intrinsically compatible with the governing bulk equations. To illustrate the interest of the many introduced jump conditions, we focus on the case of an interface between a classical Cauchy continuum on one side and a relaxed micromorphic one on the other side. As expected, we find a complete reflection in the frequency intervals for which band-gaps are known to occur in the relaxed micromorphic continuum and precise microstructure-related reflective patterns are identified. We repeat a similar study for analogous connections between a classical Cauchy continuum and a Mindlin's micromorphic one and we show that the reflective properties of the considered interfaces are drastically modified due to the fact that band-gaps are not allowed in standard Mindlin's micromorphic media. The present work opens the way towards the possibility of conceiving complex metastructures in which band-gap metamaterials and classical materials are coupled together to produce structures with completely new and unorthodox properties with respect to wave propagation, transmission and reflection. Last, but not least, indirect measurements of the material coefficients of the relaxed micromorphic model based upon real experiments of reflection and transmission in band-gap metamaterials are uncovered by the present work which makes them finally realizable in the short term.