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Tailored acoustic metamaterials. Part I. Thin- and thick-walled Helmholtz resonator arrays

M. J. A. Smith, I. David Abrahams

2022Proceedings of the Royal Society A Mathematical Physical and Engineering Sciences14 citationsDOIOpen Access PDF

Abstract

We present a novel multipole formulation for computing the band structures of two-dimensional arrays of cylindrical Helmholtz resonators. This formulation is derived by combining existing multipole methods for arrays of ideal cylinders with the method of matched asymptotic expansions. We construct asymptotically close representations for the dispersion equations of the first band surface, correcting and extending an established lowest-order (isotropic) result in the literature for thin-walled resonator arrays. The descriptions we obtain for the first band are accurate over a relatively broad frequency and Bloch vector range and not simply in the long-wavelength and low-frequency regime, as is the case in many classical treatments. Crucially, we are able to capture features of the first band, such as low-frequency anisotropy, over a broad range of filling fractions, wall thicknesses and aperture angles. In addition to describing the first band we use our formulation to compute the first band gap for both thin- and thick-walled resonators, and find that thicker resonator walls correspond to both a narrowing of the first band gap and an increase in the central band gap frequency.

Topics & Concepts

ResonatorMultipole expansionHelmholtz equationOpticsHelmholtz free energyAperture (computer memory)MetamaterialPhysicsIsotropyFrequency bandRange (aeronautics)AnisotropyMathematical analysisComputational physicsAcousticsMaterials scienceMathematicsTelecommunicationsComputer scienceQuantum mechanicsAntenna (radio)Boundary value problemComposite materialAcoustic Wave Phenomena ResearchMetamaterials and Metasurfaces ApplicationsMicrowave Engineering and Waveguides
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