A reconfigurable magnetorheological elastomer acoustic metamaterial

Resonant acoustic metamaterials (AMMs) are structures with intrinsic resonances designed to interact with acoustic wavefields to enable applications like low-frequency sound mitigation using materials much smaller than the wavelength affected. However, the addressable frequency range of the AMM is s...

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Published in:Applied physics letters 2020-09, Vol.117 (10)
Main Authors: Willey, C. L., Chen, V. W., Scalzi, K. J., Buskohl, P. R., Juhl, A. T.
Format: Article
Language:English
Subjects:
Acoustic resonance
Acoustics
Applied physics
Construction materials
Elastomers
Frequency ranges
Metamaterials
Neodymium
Permanent magnets
Reconfiguration
Transmission loss
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container_issue 10
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container_title Applied physics letters
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creator Willey, C. L.
Chen, V. W.
Scalzi, K. J.
Buskohl, P. R.
Juhl, A. T.
description Resonant acoustic metamaterials (AMMs) are structures with intrinsic resonances designed to interact with acoustic wavefields to enable applications like low-frequency sound mitigation using materials much smaller than the wavelength affected. However, the addressable frequency range of the AMM is set at the time of manufacture by the geometry, materials, and construction. In this work, a reconfigurable magnetorheological elastomer (MRE)-based AMM is proposed to alter the addressable frequency range without the need for remanufacture. By changing the spatial placement and the mass of neodymium magnets attached to the MRE plate by magnetic attraction, it is possible to engineer the mode shape of the MRE-AMM and tune the absorption, transmission loss, and effective density. It is shown through simulations and experiments that the MRE-AMM can affect wavelengths in air up to 13 170× greater than its own thickness.
doi_str_mv 10.1063/5.0015645
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source American Institute of Physics:Jisc Collections:Transitional Journals Agreement 2021-23 (Reading list); AIP_美国物理联合会现刊(与NSTL共建)
subjects Acoustic resonance
Acoustics
Applied physics
Construction materials
Elastomers
Frequency ranges
Metamaterials
Neodymium
Permanent magnets
Reconfiguration
Transmission loss
title A reconfigurable magnetorheological elastomer acoustic metamaterial
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