Non-reciprocal wave phenomena in spring-mass chains with effective stiffness modulation induced by geometric nonlinearity

TL;DR

This paper models a spring-mass chain with geometric nonlinearity that induces effective stiffness modulation, leading to non-reciprocal wave phenomena useful for designing direction-dependent acoustic devices.

Contribution

It introduces a novel model where geometric nonlinearity modulates effective stiffness, enabling non-reciprocal wave effects in discrete spring-mass chains.

Findings

Slow, nonlinear deformation modulates material properties.

Small-on-large analysis accurately predicts wave behavior.

Tuning parameters controls non-reciprocal effects.

Abstract

Acoustic non-reciprocity has been shown to enable a plethora of effects analogous to phenomena seen in quantum physics and electromagnetics, such as immunity from back-scattering and unidirectional band gaps, which could lead to the design of direction-dependent acoustic devices. One way to break reciprocity is by spatiotemporally modulating material properties, which breaks parity and time-reversal symmetries. In this work, we present a model for a medium in which a slow, nonlinear deformation modulates the effective material properties for small, overlaid disturbances (often referred to as 'small-on-large' propagation). The medium is modeled as a discrete spring-mass chain that undergoes large deformation via prescribed displacements of certain points in the unit cell. A multiple-scale perturbation analysis shows that, for sufficiently slow modulations, the small-scale waves can be described by a linear, monatomic chain with time- and space-dependent on-site stiffness. The modulation depth can be tuned by changing the geometric and stiffness parameters of the unit cell. The accuracy of the small-on-large approximation is demonstrated using direct numerical simulations.