Low-frequency sound absorbing metasurface using multilayer split resonators

Shota Takasugi; Keita Watanabe; Masaaki Misawa; Kenji Tsuruta

doi:10.35848/1347-4065/abe2e5

Low-frequency sound absorbing metasurface using multilayer split resonators

Shota Takasugi, Keita Watanabe, Masaaki Misawa, Kenji Tsuruta

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

6 Citations (Scopus)

Abstract

Among the acoustic metasurfaces that can control the propagation of sound waves with the structure far thinner than the wavelength at the operating frequency, the split tube structure has shown its effectiveness in the lower frequency band. Here we focus on multiply layered split tubes to broaden the absorption spectrum. By numerical analysis, we show up-to six-layer structure possessing wideband (1-1000 Hz) sound absorption. The absorbing peaks in the frequency band below 1000 Hz are shown to be multiplexed not only by simple superposition of vibrational modes of each layer, but also by hybridization of the modes indicating collective motion of tubes.

Original language	English
Article number	abe2e5
Journal	Japanese Journal of Applied Physics
Volume	60
Issue number	SD
DOIs	https://doi.org/10.35848/1347-4065/abe2e5
Publication status	Published - Jul 2021

ASJC Scopus subject areas

Engineering(all)
Physics and Astronomy(all)

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10.35848/1347-4065/abe2e5

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title = "Low-frequency sound absorbing metasurface using multilayer split resonators",

abstract = "Among the acoustic metasurfaces that can control the propagation of sound waves with the structure far thinner than the wavelength at the operating frequency, the split tube structure has shown its effectiveness in the lower frequency band. Here we focus on multiply layered split tubes to broaden the absorption spectrum. By numerical analysis, we show up-to six-layer structure possessing wideband (1-1000 Hz) sound absorption. The absorbing peaks in the frequency band below 1000 Hz are shown to be multiplexed not only by simple superposition of vibrational modes of each layer, but also by hybridization of the modes indicating collective motion of tubes.",

author = "Shota Takasugi and Keita Watanabe and Masaaki Misawa and Kenji Tsuruta",

note = "Funding Information: This work was supported in part by the JSPS KAKENHI Grant No. 17K19035. Publisher Copyright: {\textcopyright} 2021 The Japan Society of Applied Physics",

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AU - Takasugi, Shota

AU - Watanabe, Keita

AU - Misawa, Masaaki

AU - Tsuruta, Kenji

PY - 2021/7

Y1 - 2021/7

N2 - Among the acoustic metasurfaces that can control the propagation of sound waves with the structure far thinner than the wavelength at the operating frequency, the split tube structure has shown its effectiveness in the lower frequency band. Here we focus on multiply layered split tubes to broaden the absorption spectrum. By numerical analysis, we show up-to six-layer structure possessing wideband (1-1000 Hz) sound absorption. The absorbing peaks in the frequency band below 1000 Hz are shown to be multiplexed not only by simple superposition of vibrational modes of each layer, but also by hybridization of the modes indicating collective motion of tubes.

AB - Among the acoustic metasurfaces that can control the propagation of sound waves with the structure far thinner than the wavelength at the operating frequency, the split tube structure has shown its effectiveness in the lower frequency band. Here we focus on multiply layered split tubes to broaden the absorption spectrum. By numerical analysis, we show up-to six-layer structure possessing wideband (1-1000 Hz) sound absorption. The absorbing peaks in the frequency band below 1000 Hz are shown to be multiplexed not only by simple superposition of vibrational modes of each layer, but also by hybridization of the modes indicating collective motion of tubes.

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Low-frequency sound absorbing metasurface using multilayer split resonators

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