Closed-form existence conditions for band-gap resonances in a finite periodic chain under general boundary conditions

TL;DR

This paper derives explicit conditions for the existence of band-gap resonances in finite diatomic chains with various boundary conditions, enhancing understanding of boundary effects in periodic media.

Contribution

It provides closed-form existence conditions for band-gap resonances in finite diatomic chains with general boundary conditions and chain parity, extending prior free-free boundary results.

Findings

Conditions are consistent with prior theoretical and experimental results.

Introducing an arbitrary end mass causes a transition among existence conditions.

Analysis applies to both lumped-parameter and continuous granular media models.

Abstract

Bragg scattering in periodic media generates band gaps, frequency bands where waves attenuate rather than propagate. Yet, a finite periodic structure may exhibit resonance frequencies within these band gaps. This is caused by boundary effects introduced by the truncation of the nominal infinite medium. Previous studies of discrete systems determined existence conditions for band-gap resonances, although the focus has been limited to periodic chains with free-free boundaries. In this paper, we present closed-form existence conditions for band-gap resonances in discrete diatomic chains with general boundary conditions (free-free, free-fixed, fixed-free, or fixed-fixed), odd or even chain parity (contrasting or identical masses at the ends), and the possibility of attaching a unique component (mass and/or spring) at one or both ends. The derived conditions are consistent with those theoretically presented or experimentally observed in prior studies of structures that can be modeled as linear discrete diatomic chains with free-free boundary conditions. An intriguing case is a free-free chain with even parity and an arbitrary additional mass at one end of the chain. Introducing such an arbitrary mass underscores a transition among a set of distinct existence conditions depending on the type of the chain boundaries and parity. The proposed analysis is applicable to linear periodic chains in the form of lumped-parameter models as well as continuous granular media models examined in the low-frequency regime.