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Nonlocal boundary conditions for corrugated acoustic metasurface with strong near field interactions

Schwan, L; Umnova, O; Boutin, C; Groby, JP

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Authors

L Schwan

O Umnova

C Boutin

JP Groby



Abstract

The propagation of long-wavelength sound in the presence of a metasurface made by arranging acoustic resonators periodically upon or slightly above an impervious substrate is studied. The method of two-scale asymptotic homogenization is used to derive effective boundary conditions, which account for both the surface corrugation and the low-frequency resonance. This method is applied to periodic arrays of resonators of any shape operating in the long-wavelength regime. The approach relies on the existence of a locally periodic boundary layer developed in the vicinity of the metasurface, where strong near-field interactions of the resonators with each other and with the substrate take place. These local effects give rise to an effective surface admittance supplemented by nonlocal contributions from the simple and double gradients of the pressure at the surface. These phenomena are illustrated for the periodic array of cylindrical Helmholtz resonators with an extended inner duct. Effects of the centre-to-centre spacing and orientation of the resonators' opening on the nonlocality and apparent resonance frequency are studied. The model could be used to design metasurfaces with specific effective boundary conditions required for particular applications.

Citation

Schwan, L., Umnova, O., Boutin, C., & Groby, J. (2018). Nonlocal boundary conditions for corrugated acoustic metasurface with strong near field interactions. Journal of Applied Physics, 123, 091712. https://doi.org/10.1063/1.5011385

Journal Article Type Article
Acceptance Date Jan 8, 2018
Online Publication Date Jan 24, 2018
Publication Date Jan 24, 2018
Deposit Date Jan 30, 2018
Publicly Available Date Jan 24, 2019
Journal Journal of Applied Physics
Print ISSN 0021-8979
Electronic ISSN 1089-7550
Publisher AIP Publishing
Volume 123
Pages 091712
DOI https://doi.org/10.1063/1.5011385
Publisher URL http://dx.doi.org/10.1063/1.5011385
Related Public URLs http://aip.scitation.org/journal/jap
Additional Information Funders : Engineering and Physical Sciences Research Council (EPSRC)
Projects : Periodicity enhanced attenuating layers and structures
Grant Number: EP/ K037234/1

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