Wave transmission in time- and space-variant helicoidal phononic crystals

F. Li; C. Chong; J. Yang; P. G. Kevrekidis; C. Daraio

doi:10.1103/PhysRevE.90.053201

Wave transmission in time- and space-variant helicoidal phononic crystals

F. Li^*, C. Chong, J. Yang, P. G. Kevrekidis, C. Daraio

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

28 Citations (Scopus)

Abstract

We present a dynamically tunable mechanism of wave transmission in one-dimensional helicoidal phononic crystals in a shape similar to DNA structures. These helicoidal architectures allow slanted nonlinear contact among cylindrical constituents, and the relative torsional movements can dynamically tune the contact stiffness between neighboring cylinders. This results in cross-talking between in-plane torsional and out-of-plane longitudinal waves. We numerically demonstrate their versatile wave mixing and controllable dispersion behavior in both wavenumber and frequency domains. Based on this principle, a suggestion toward an acoustic configuration bearing parallels to a transistor is further proposed, in which longitudinal waves can be switched on and off through torsional waves.

Original language	English
Article number	053201
Journal	Physical Review E
Volume	90
Issue number	5
DOIs	https://doi.org/10.1103/PhysRevE.90.053201
Publication status	Published - 4 Nov 2014
Externally published	Yes

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title = "Wave transmission in time- and space-variant helicoidal phononic crystals",

abstract = "We present a dynamically tunable mechanism of wave transmission in one-dimensional helicoidal phononic crystals in a shape similar to DNA structures. These helicoidal architectures allow slanted nonlinear contact among cylindrical constituents, and the relative torsional movements can dynamically tune the contact stiffness between neighboring cylinders. This results in cross-talking between in-plane torsional and out-of-plane longitudinal waves. We numerically demonstrate their versatile wave mixing and controllable dispersion behavior in both wavenumber and frequency domains. Based on this principle, a suggestion toward an acoustic configuration bearing parallels to a transistor is further proposed, in which longitudinal waves can be switched on and off through torsional waves.",

author = "F. Li and C. Chong and J. Yang and Kevrekidis, {P. G.} and C. Daraio",

note = "Publisher Copyright: {\textcopyright} 2014 American Physical Society.",

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AU - Li, F.

AU - Chong, C.

AU - Yang, J.

AU - Kevrekidis, P. G.

AU - Daraio, C.

PY - 2014/11/4

Y1 - 2014/11/4

N2 - We present a dynamically tunable mechanism of wave transmission in one-dimensional helicoidal phononic crystals in a shape similar to DNA structures. These helicoidal architectures allow slanted nonlinear contact among cylindrical constituents, and the relative torsional movements can dynamically tune the contact stiffness between neighboring cylinders. This results in cross-talking between in-plane torsional and out-of-plane longitudinal waves. We numerically demonstrate their versatile wave mixing and controllable dispersion behavior in both wavenumber and frequency domains. Based on this principle, a suggestion toward an acoustic configuration bearing parallels to a transistor is further proposed, in which longitudinal waves can be switched on and off through torsional waves.

AB - We present a dynamically tunable mechanism of wave transmission in one-dimensional helicoidal phononic crystals in a shape similar to DNA structures. These helicoidal architectures allow slanted nonlinear contact among cylindrical constituents, and the relative torsional movements can dynamically tune the contact stiffness between neighboring cylinders. This results in cross-talking between in-plane torsional and out-of-plane longitudinal waves. We numerically demonstrate their versatile wave mixing and controllable dispersion behavior in both wavenumber and frequency domains. Based on this principle, a suggestion toward an acoustic configuration bearing parallels to a transistor is further proposed, in which longitudinal waves can be switched on and off through torsional waves.

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Wave transmission in time- and space-variant helicoidal phononic crystals

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