Deaf band-based prediction of Dirac cone in acoustic metamaterials

Mustahseen M. Indaleeb; Hossain Ahmed; Mohammadsadegh Saadatzi; Sourav Banerjee

doi:10.1063/1.5122297

Deaf band-based prediction of Dirac cone in acoustic metamaterials

Mustahseen M. Indaleeb, Hossain Ahmed, Mohammadsadegh Saadatzi, Sourav Banerjee

Mechanical Engineering

University of South Carolina

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

14 Scopus citations

Abstract

Through an alternative paradigm, a predictive design of a Dirac-like point is introduced in a linear periodic metamaterial for the spatial guidance of acoustic waves. Dirac conelike dispersion at the Cyrillic capital letter GHE point (for k → = 0) in a Brillouin zone is called a "Dirac-like cone," which seldom occurs due to accidental degeneracy. However, a deaf band-based predictive model shows incredible potential to achieve an engineered Dirac cone at a predictive pivoted frequency. A targeted Dirac cone at a higher frequency is carried out in this article validating the orthogonal energy transport in a spiral pattern. The dominance of asymmetric deaf band modes triggers total internal reflection and guiding of acoustic waves inside phononic crystals. To elucidate the versatility of this methodology, experimental validation of orthogonal wave transport is presented.

Original language	English
Article number	064903
Journal	Journal of Applied Physics
Volume	127
Issue number	6
DOIs	https://doi.org/10.1063/1.5122297
State	Published - Feb 14 2020

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General Physics and Astronomy

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AB - Through an alternative paradigm, a predictive design of a Dirac-like point is introduced in a linear periodic metamaterial for the spatial guidance of acoustic waves. Dirac conelike dispersion at the Cyrillic capital letter GHE point (for k → = 0) in a Brillouin zone is called a "Dirac-like cone," which seldom occurs due to accidental degeneracy. However, a deaf band-based predictive model shows incredible potential to achieve an engineered Dirac cone at a predictive pivoted frequency. A targeted Dirac cone at a higher frequency is carried out in this article validating the orthogonal energy transport in a spiral pattern. The dominance of asymmetric deaf band modes triggers total internal reflection and guiding of acoustic waves inside phononic crystals. To elucidate the versatility of this methodology, experimental validation of orthogonal wave transport is presented.

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Deaf band-based prediction of Dirac cone in acoustic metamaterials

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