Dissipation engineering in metamaterials by localized structural dynamics

TL;DR

This paper introduces a theory for dissipation engineering in elastic metamaterials by embedding localized substructures, enabling control over wave damping characteristics for advanced material design.

Contribution

It extends structural dynamics to materials engineering, providing a validated theory for tuning dissipation via substructural design in metamaterials.

Findings

Demonstrates regimes of enhanced and reduced dissipation (positive and negative metadamping)

Validates theory with experiments on elastic beams with attached pillars

Identifies dissipation regimes using band structure and wavenumber analysis

Abstract

In civil, mechanical, and aerospace engineering, structural dynamics is commonly understood to be a discipline concerned with the analysis and characterization of the vibratory response of structures. Key elements of the response are the amplitude, phase, and damping ratio, which are quantities that vary with the excitation frequency. In this paper, we extend the discipline of structural dynamics to the realm of materials engineering by intrinsically building localized substructures within, or attached to, the material domain itself$-$which is viewed as an extended medium without defined external boundaries. Our system is essentially a locally resonant elastic metamaterial, except here it is viewed from the perspective of unique dissipation characteristics rather than subwavelength effective properties or band gaps, as widely done in the literature. We provide a theory, validated by experiments, for substructurally synthesizing the dissipation under the conditions of free-wave motion, i.e., waves not constrained to a prescribed driving frequency. We use an extended elastic beam with attached pillars as an example of a metamaterial. When compared to an identical infinite beam with no attached substructures, we show that within certain frequency ranges the metamaterial exhibits either enhanced or reduced dissipation$-$which we refer to as positive and negative metadamping, respectively. These regimes are rigorously identified and characterized using the metamaterial's band structure and wavenumber-dependent dissipation diagram. This theory impacts applications that require a combination of high stiffness and high damping or, conversely, applications that benefit from a reduction in loss without the need to change the backbone constituent material.