MODELING ACOUSTIC SPACE-COILED METACRYSTALS*

Joar Zhou Hagstrom; Kim Pham; Agnes Maurel

doi:10.1137/22M1527131

MODELING ACOUSTIC SPACE-COILED METACRYSTALS^*

Joar Zhou Hagstrom
, Kim Pham
, Agnes Maurel

PSL Research University

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

Abstract

We present an effective model of ``space-coiled metacrystals"" composed of a periodic array of sound rigid blocks into which long slots have been coiled up. The periodic cell of the block contains a coiled slot whose straight parts are at wavelength scale, which enables the appearance of Bragg resonances. These resonances, which prevent high transmission, compete with the Fabry-P\'erot resonances of the entire slot, which foster perfect transmission. This results in complex scattering properties driven by the characteristics of the turning regions that act as atoms in a one-dimensional coiled crystal. Using appropriate scaling and combining two-scale homogenization with matched asymptotic techniques, the modeling of such metacrystals is proposed. The resulting model is validated through a comparison with full-wave numerics in both harmonic and transient regimes.

Original language	English
Pages (from-to)	2499-2521
Number of pages	23
Journal	SIAM Journal on Applied Mathematics
Volume	83
Issue number	6
DOIs	https://doi.org/10.1137/22M1527131
Publication status	Published - 1 Jan 2023

Keywords

asymptotic analysis
crystal
resonant metasurface
space-coiling
two-scale homogenization

Access to Document

10.1137/22M1527131

Cite this

@article{34235da172eb4aa984648ff56f111c82,

title = "MODELING ACOUSTIC SPACE-COILED METACRYSTALS*",

abstract = "We present an effective model of ``space-coiled metacrystals{"}{"} composed of a periodic array of sound rigid blocks into which long slots have been coiled up. The periodic cell of the block contains a coiled slot whose straight parts are at wavelength scale, which enables the appearance of Bragg resonances. These resonances, which prevent high transmission, compete with the Fabry-P\textbackslash{}'erot resonances of the entire slot, which foster perfect transmission. This results in complex scattering properties driven by the characteristics of the turning regions that act as atoms in a one-dimensional coiled crystal. Using appropriate scaling and combining two-scale homogenization with matched asymptotic techniques, the modeling of such metacrystals is proposed. The resulting model is validated through a comparison with full-wave numerics in both harmonic and transient regimes.",

keywords = "asymptotic analysis, crystal, resonant metasurface, space-coiling, two-scale homogenization",

author = "Hagstrom, \{Joar Zhou\} and Kim Pham and Agnes Maurel",

year = "2023",

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doi = "10.1137/22M1527131",

language = "English",

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journal = "SIAM Journal on Applied Mathematics",

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TY - JOUR

T1 - MODELING ACOUSTIC SPACE-COILED METACRYSTALS*

AU - Hagstrom, Joar Zhou

AU - Pham, Kim

AU - Maurel, Agnes

PY - 2023/1/1

Y1 - 2023/1/1

N2 - We present an effective model of ``space-coiled metacrystals"" composed of a periodic array of sound rigid blocks into which long slots have been coiled up. The periodic cell of the block contains a coiled slot whose straight parts are at wavelength scale, which enables the appearance of Bragg resonances. These resonances, which prevent high transmission, compete with the Fabry-P\'erot resonances of the entire slot, which foster perfect transmission. This results in complex scattering properties driven by the characteristics of the turning regions that act as atoms in a one-dimensional coiled crystal. Using appropriate scaling and combining two-scale homogenization with matched asymptotic techniques, the modeling of such metacrystals is proposed. The resulting model is validated through a comparison with full-wave numerics in both harmonic and transient regimes.

AB - We present an effective model of ``space-coiled metacrystals"" composed of a periodic array of sound rigid blocks into which long slots have been coiled up. The periodic cell of the block contains a coiled slot whose straight parts are at wavelength scale, which enables the appearance of Bragg resonances. These resonances, which prevent high transmission, compete with the Fabry-P\'erot resonances of the entire slot, which foster perfect transmission. This results in complex scattering properties driven by the characteristics of the turning regions that act as atoms in a one-dimensional coiled crystal. Using appropriate scaling and combining two-scale homogenization with matched asymptotic techniques, the modeling of such metacrystals is proposed. The resulting model is validated through a comparison with full-wave numerics in both harmonic and transient regimes.

KW - asymptotic analysis

KW - crystal

KW - resonant metasurface

KW - space-coiling

KW - two-scale homogenization

U2 - 10.1137/22M1527131

DO - 10.1137/22M1527131

M3 - Article

AN - SCOPUS:85180122726

SN - 0036-1399

VL - 83

SP - 2499

EP - 2521

JO - SIAM Journal on Applied Mathematics

JF - SIAM Journal on Applied Mathematics

IS - 6