A new method to identify elastic wave propagation mode and polarized bandgaps in periodic solid media

TL;DR

This paper introduces a novel computational method to accurately identify elastic wave modes and polarized bandgaps in periodic solid structures, enhancing analysis of wave propagation and bandgap phenomena in metamaterials.

Contribution

The paper presents a new computational approach that uses eigenvector analysis and polarization factors to identify wave modes and polarizations, improving upon traditional visual inspection methods.

Findings

Validated method against existing results for elastodynamic problems.

Discovered new polarized bandgaps and fluid-like behaviors in lattice structures.

Extended understanding of low-frequency bandgap phenomena.

Abstract

We present a new computational method for the accurate identification of the propagation modes and polarizations of elastic waves propagating in periodic solid structures and metamaterials. The method uses the eigenvectors calculated at each propagating wave solution eigenfrequency to identify the contribution of each translational and rotational component of the total mass in motion. We use this information to identify the dominant wave propagation mode by defining a relative effective modal mass vector. Further, we associate each wave solution with its correct polarization by defining a new polarization factor that quantifies the relative orientation between the wave propagation and lattice motion directions and provides a positive numerical value between 0 (pure S-wave) and 1 (pure P-wave). Further, we suggest a graphical representational scheme for an easier visualization of the wave polarization within traditional dispersion plots. The method is validated by comparing our predictions against previously published results for various elastodynamic problems. Finally, we use the proposed method to analyze the effect of various lattice and structural parameter perturbations on the elastic wave propagation and bandgap behavior of a square planar beam lattice and show the emergence of previously unobserved dynamic characteristics, including various polarized bandgaps, fluid-like behavior, and ultralow-frequency SH- and SV-bandgaps that extend to 0 Hz. The proposed method provides an alternative computational approach to the typically employed visual mode inspection technique and provides a robust technique for analyzing the elastic wave response of periodic solid media.