Kirigami-based Elastic Metamaterials with Anisotropic Mass Density for Subwavelength Flexural Wave Control

TL;DR

This paper introduces a kirigami-inspired elastic metamaterial with anisotropic mass density that enables subwavelength control of flexural waves without perforating the host plate, useful for advanced wave manipulation and imaging.

Contribution

It presents a novel kirigami-based design for elastic metamaterials that achieve anisotropic mass density and subwavelength wave control without damaging the host structure.

Findings

Demonstrates anisotropic effective mass density due to local resonance and wave coupling.

Shows directional flexural wave manipulation through numerical simulations.

Achieves super-resolution imaging with an elastic hyperlens.

Abstract

A novel design of an elastic metamaterial with anisotropic mass density is proposed to manipulate flexural waves at a subwavelength scale. The three-dimensional metamaterial is inspired by kirigami, which can be easily manufactured by cutting and folding a thin metallic plate. By attaching the resonant kirigami structures periodically on the top of a host plate, a metamaterial plate can be constructed without any perforation that degrades the strength of the pristine plate. An analytical model is developed to understand the working mechanism of the proposed elastic metamaterial and the dispersion curves are calculated by using an extended plane wave expansion method. As a result, we verify an anisotropic effective mass density stemming from the coupling between the local resonance of the kirigami cells and the global flexural wave propagations in the host plate. Finally, numerical simulations on the directional flexural wave propagation in a two-dimensional array of kirigami metamaterial as well as super-resolution imaging through an elastic hyperlens are conducted to demonstrate the subwavelength-scale flexural wave control abilities. The proposed kirigami-based metamaterial has the advantages of no-perforation design and subwavelength flexural wave manipulation capability, which can be highly useful for engineering applications including non-destructive evaluations and structural health monitoring.