Simplified modelling of chiral lattice materials with local resonators

TL;DR

This paper introduces a simplified discrete and continuum model for chiral lattice materials with local resonators, analyzing their band structure and acoustic properties, including low-frequency band-gaps, through a combined discrete and micropolar continuum approach.

Contribution

A novel simplified modeling framework combining discrete Lagrangian and micropolar continuum models for chiral lattices with local resonators, enhancing understanding of their dynamic behavior.

Findings

Identification of two acoustic and four optical modes in chiral lattices.

Analysis of the influence of resonator dynamics on band structure.

Validation of the micropolar model against discrete model dispersion curves.

Abstract

A simplified model of periodic chiral beam-lattices containing local resonators has been formulated to obtain a better understanding of the influence of the chirality and of the dynamic characteristics of the local resonators on the acoustic behavior. The simplified beam-lattices is made up of a periodic array of rigid heavy rings, each one connected to the others through elastic slender massless ligaments and containing an internal resonator made of a rigid disk in a soft elastic annulus. The band structure and the occurrence of low frequency band-gaps are analysed through a discrete Lagrangian model. For both the hexa- and the tetrachiral lattice, two acoustic modes and four optical modes are identified and the influence of the dynamic characteristics of the resonator on those branches is analyzed together with some properties of the band structure. By approximating the generalized displacements of the rings of the discrete Lagrangian model as a continuum field and through an application of the generalized macro-homogeneity condition, a generalized micropolar equivalent continuum has been derived, together with the overall equation of motion and the constitutive equation given in closed form. The validity limits of the micropolar model with respect to the dispersion functions are assessed by comparing the dispersion curves of this model in the irreducible Brillouin domain with those obtained by the discrete model, which are exact within the assumptions of the proposed simplified model.