Experimental demonstration of negative refraction with 3D locally resonant acoustic metafluids

Experimental demonstration of negative refraction with 3D locally resonant acoustic metafluids

Abstract Negative refraction of acoustic waves is demonstrated through underwater experiments conducted at ultrasonic frequencies on a 3D locally resonant acoustic metafluid made of soft porous silicone-rubber micro-beads suspended in a yield-stress fluid. By measuring the refracted angle of the aco...

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Main Authors: Benoit Tallon, Artem Kovalenko, Olivier Poncelet, Christophe Aristégui, Olivier Mondain-Monval, Thomas Brunet
Format: Article
Language:English
Published: Nature Publishing Group 2021-02-01
Series:Scientific Reports
Online Access:https://doi.org/10.1038/s41598-021-84018-x
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spelling doaj-10a6631007514c6eaecb718e26dc37f42021-03-11T12:16:48ZengNature Publishing GroupScientific Reports2045-23222021-02-011111610.1038/s41598-021-84018-xExperimental demonstration of negative refraction with 3D locally resonant acoustic metafluidsBenoit Tallon0Artem Kovalenko1Olivier Poncelet2Christophe Aristégui3Olivier Mondain-Monval4Thomas Brunet5Univ. Bordeaux - CNRS - Bordeaux INP - ENSAM, I2MUniv. Bordeaux - CNRS, CRPPUniv. Bordeaux - CNRS - Bordeaux INP - ENSAM, I2MUniv. Bordeaux - CNRS - Bordeaux INP - ENSAM, I2MUniv. Bordeaux - CNRS, CRPPUniv. Bordeaux - CNRS - Bordeaux INP - ENSAM, I2MAbstract Negative refraction of acoustic waves is demonstrated through underwater experiments conducted at ultrasonic frequencies on a 3D locally resonant acoustic metafluid made of soft porous silicone-rubber micro-beads suspended in a yield-stress fluid. By measuring the refracted angle of the acoustic beam transmitted through this metafluid shaped as a prism, we determine the acoustic index to water according to Snell’s law. These experimental data are then compared with an excellent agreement to calculations performed in the framework of Multiple Scattering Theory showing that the emergence of negative refraction depends on the volume fraction $$\Phi$$ Φ of the resonant micro-beads. For diluted metafluid ( $$\Phi =3\%$$ Φ = 3 % ), only positive refraction occurs whereas negative refraction is demonstrated over a broad frequency band with concentrated metafluid ( $$\Phi =17\%$$ Φ = 17 % ).https://doi.org/10.1038/s41598-021-84018-x
collection DOAJ
language English
format Article
sources DOAJ
author Benoit Tallon
Artem Kovalenko
Olivier Poncelet
Christophe Aristégui
Olivier Mondain-Monval
Thomas Brunet
spellingShingle Benoit Tallon
Artem Kovalenko
Olivier Poncelet
Christophe Aristégui
Olivier Mondain-Monval
Thomas Brunet
Experimental demonstration of negative refraction with 3D locally resonant acoustic metafluids
Scientific Reports
author_facet Benoit Tallon
Artem Kovalenko
Olivier Poncelet
Christophe Aristégui
Olivier Mondain-Monval
Thomas Brunet
author_sort Benoit Tallon
title Experimental demonstration of negative refraction with 3D locally resonant acoustic metafluids
title_short Experimental demonstration of negative refraction with 3D locally resonant acoustic metafluids
title_full Experimental demonstration of negative refraction with 3D locally resonant acoustic metafluids
title_fullStr Experimental demonstration of negative refraction with 3D locally resonant acoustic metafluids
title_full_unstemmed Experimental demonstration of negative refraction with 3D locally resonant acoustic metafluids
title_sort experimental demonstration of negative refraction with 3d locally resonant acoustic metafluids
publisher Nature Publishing Group
series Scientific Reports
issn 2045-2322
publishDate 2021-02-01
description Abstract Negative refraction of acoustic waves is demonstrated through underwater experiments conducted at ultrasonic frequencies on a 3D locally resonant acoustic metafluid made of soft porous silicone-rubber micro-beads suspended in a yield-stress fluid. By measuring the refracted angle of the acoustic beam transmitted through this metafluid shaped as a prism, we determine the acoustic index to water according to Snell’s law. These experimental data are then compared with an excellent agreement to calculations performed in the framework of Multiple Scattering Theory showing that the emergence of negative refraction depends on the volume fraction $$\Phi$$ Φ of the resonant micro-beads. For diluted metafluid ( $$\Phi =3\%$$ Φ = 3 % ), only positive refraction occurs whereas negative refraction is demonstrated over a broad frequency band with concentrated metafluid ( $$\Phi =17\%$$ Φ = 17 % ).
url https://doi.org/10.1038/s41598-021-84018-x
work_keys_str_mv AT benoittallon experimentaldemonstrationofnegativerefractionwith3dlocallyresonantacousticmetafluids
AT artemkovalenko experimentaldemonstrationofnegativerefractionwith3dlocallyresonantacousticmetafluids
AT olivierponcelet experimentaldemonstrationofnegativerefractionwith3dlocallyresonantacousticmetafluids
AT christophearistegui experimentaldemonstrationofnegativerefractionwith3dlocallyresonantacousticmetafluids
AT oliviermondainmonval experimentaldemonstrationofnegativerefractionwith3dlocallyresonantacousticmetafluids
AT thomasbrunet experimentaldemonstrationofnegativerefractionwith3dlocallyresonantacousticmetafluids
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