Effect of prestress on phononic band gaps induced by inertial amplification

TL;DR

This paper investigates how external mechanical loads, specifically prestress, can significantly tune the band gaps in inertial amplification phononic structures, enabling real-time wave control.

Contribution

It introduces a novel analytical and computational framework to analyze prestress effects on inertial amplification band gaps, revealing reversible and substantial tunability.

Findings

Prestress causes up to twofold change in band gap width.

External load shifts dispersion branches, potentially causing negative group velocities.

A new 2-step calculation method effectively models the prestress impact on band gaps.

Abstract

We report about the effect of an applied external mechanical load on a periodic structure exhibiting band gaps induced by inertial amplification mechanism. If compared to the cases of Bragg scattering and ordinary local resonant metamaterials, we observe here a more remarkable curve shift, modulated through large but fully reversible compression(stretch) of the unit cell, eventually triggering significant (up to two times) enlargement(reduction) of the width of a specific band gap. An important up(down)-shift of some dispersion branches over specific wavenumber values is also observed, showing that this selective variation may lead to negative group velocities over larger(smaller) wavenumber ranges. The possibility for a non-monotone trend of the lower limit of the first BG under the same type of external applied prestrain is found and explained through an analytical model, which unequivocally proves that this behavior derives from the different unit cell effective mass and stiffness variations as the prestrain level increases. The effect of the prestress on the dispersion diagram is investigated through the development of a 2-step calculation method: first, an Updated Lagrangian scheme, including a static geometrically nonlinear analysis of a representative unit cell undergoing the action of an applied external load is derived, and then the Floquet-Bloch decomposition is applied to the linearized equations of the acousto-elasticity for the unit cell in the deformed configuration. The results presented herein provide insights in the behavior of band gaps induced by inertial amplification and suggest new opportunities for real-time tunable wave manipulation.