Yuezhou Luo scite author profile

Yuezhou Luo

3Publications

0Citation Statements Received

112Citation Statements Given

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105

112

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Fudan University

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Bilayer ventilated labyrinthine metasurfaces with high sound absorption and tunable bandwidth

Luo

Zhao

et al. 2021

Sci Rep

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The recent advent of acoustic metamaterials offers unprecedented opportunities for sound controlling in various occasions, whereas it remains a challenge to attain broadband high sound absorption and free air flow simultaneously. Here, we demonstrated, both theoretically and experimentally, that this problem can be overcome by using a bilayer ventilated labyrinthine metasurface. By altering the spacing between two constituent single-layer metasurfaces and adopting asymmetric losses in them, near-perfect (98.6%) absorption is achieved at resonant frequency for sound waves incident from the front. The relative bandwidth of absorption peak can be tuned in a wide range (from 12% to 80%) by adjusting the open area ratio of the structure. For sound waves from the back, the bilayer metasurface still serves as a sound barrier with low transmission. Our results present a strategy to realize high sound absorption and free air flow simultaneously, and could find applications in building acoustics and noise remediation.

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Bilayer Ventilated Labyrinthine Metasurfaces With High Sound Absorption and Tunable Bandwidth

Luo

Zhao

et al. 2021

Preprint

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The recent advent of acoustic metamaterials offers unprecedented opportunities for sound controlling in various occasions, whereas it remains a challenge to attain broadband high sound absorption and free air flow simultaneously. Here, we demonstrated, both theoretically and experimentally, that this problem can be overcome by using a bilayer ventilated labyrinthine metasurface. By altering the spacing between two constituent single-layer metasurfaces and adopting asymmetric losses in them, near-perfect (98.6%) absorption is achieved at resonant frequency for sound waves incident from the front. The relative bandwidth of absorption peak can be tuned in a wide range (from 12% to 80%) byadjusting the open area ratio of the structure. For sound waves from the back, the bilayer metasurface still serves as a sound barrier with low transmission. Our results present a strategy to realize high sound absorption and free air flow simultaneously, and could find applications in building acoustics and noise remediation.

show abstract

Bilayer ventilated labyrinthine metasurfaces with high sound absorption and tunable bandwidth

Luo

Zhao

et al. 2020

Preprint

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Yuezhou Luo

Bilayer ventilated labyrinthine metasurfaces with high sound absorption and tunable bandwidth

Bilayer Ventilated Labyrinthine Metasurfaces With High Sound Absorption and Tunable Bandwidth

Bilayer ventilated labyrinthine metasurfaces with high sound absorption and tunable bandwidth

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