Abstract
Quasiperiodic metastrucures are characterized by edge localized modes of topological nature, which can be of significant technological interest. We here investigate such topological modes for stiffened and sandwich beams, which can be employed as structural members with inherent vibration localization capabilities. Quasiperiodicity is achieved by altering the geometric properties and material properties of the beams. Specifically, in the stiffened beams, the geometric location of stiffeners is modulated to quasiperiodic patterns, while, in the sandwich beams, the core’s material properties are varied in a step-wise manner to generate such patterns. The families of periodic and quasiperiodic beams for both stiffened and sandwich-type are obtained by varying a projection parameter that governs the location of the center of the stiffener or the alternating core, respectively. The dynamics of stiffened quasiperiodic beams is investigated through 3-D finite element simulations, which leads to the observation of the fractal nature of the bulk spectrum and the illustration of topological edge modes that populate bulk spectral bandgaps. The frequency spectrum is further elucidated by employing polarization factors that distinguish multiple contributing modes. The frequency response of the finite stiffened cantilever beams confirms the presence of modes in the non-trivial bandgaps and further demonstrates that those modes are localized at the free edge. A similar analysis is conducted for the analysis of sandwich composite beams, for which computations rely on a dynamic stiffness matrix approach. This work motivates the use of quasiperiodic beams in the design of stiffened and sandwich structures as structural members in applications where vibration isolation is combined with load-carrying functions.
Highlights
Topological modes such as edge modes or interface modes are present in topological metastructures [1,2]
We demonstrate the occurrence of topological bandgaps, locally resonant modes, and the frequency response function using the 3-D Finite Element Method (FEM) in COMSOL [38,39]
We study the dynamic behavior of quasiperiodic structural beams built with two distinct characteristics
Summary
Topological modes such as edge modes or interface modes are present in topological metastructures [1,2]. To elucidate the separate contributions of the various modes of deformation, we employ a polarization factor with the aim to identify contributions associated with bending (out-of-plane, in-plane), longitudinal, torsional, etc This process helps us entangle the bulk spectrum for beams, which takes the form of the well-known. The paper comprises the detailed methodology to obtain the mode polarizations, the Hofstadter butterfly, and the demonstration of locally resonant modes of the infinite and finite metastructures, respectively, that span the non-trivial bandgaps [4,5,32,37]. Quasiperiodic arrangements of the alternating core materials in sandwich beams are considered and the dynamics of such beams are studied using a suitable dynamic stiffness matrix to obtain the frequency spectrum in the form of a Hofstadter butterfly.
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