Linear and nonlinear dynamics of isospectral granular chains

TL;DR

This paper explores how the dynamics of isospectral granular chains can be tuned from linear to nonlinear using initial compression, introducing spectral transformation schemes and supersymmetry-inspired methods to manipulate eigenfrequencies and wave transmission.

Contribution

It presents novel spectral transformation schemes and a supersymmetry-inspired methodology to control eigenfrequencies in granular chains, bridging linear and nonlinear dynamics.

Findings

Isospectral chains exhibit similar linear wave transmission characteristics.

Nonlinearity causes deviations from linear isospectral behavior.

The framework enables tailored wave transmission in granular systems.

Abstract

We study the dynamics of isospectral granular chains that are highly tunable due to the nonlinear Hertz contact law interaction between the granular particles. The system dynamics can thus be tuned easily from being linear to strongly nonlinear by adjusting the initial compression applied to the chain. In particular, we introduce both discrete and continuous spectral transformation schemes to generate a family of granular chains that are isospectral in their linear limit. Inspired by the principle of supersymmetry in quantum systems, we also introduce a methodology to add or remove certain eigenfrequencies, and we demonstrate numerically that the corresponding physical system can be constructed in the setting of one-dimensional granular crystals. In the linear regime, we highlight the commonalities and differences in the elastic wave transmission characteristics of such isospectral systems, and emphasize that the presented mathematical framework allows one to suitably tailor the wave transmission through a general class of granular chains. Moreover, we show how the dynamic response of these structures deviates from its linear limit as we introduce Hertzian nonlinearity in the chain and how nonlinearity breaks the notion of linear isospectrality.