Sound absorption by acoustic microlattice with optimized pore configuration

Xiaobing Cai; Jun Yang; Gengkai Hu; Tianjian Lu

doi:10.1121/1.5051526

Sound absorption by acoustic microlattice with optimized pore configuration

Xiaobing Cai
, Jun Yang
, Gengkai Hu
, Tianjian Lu

Western University
Beijing Institute of Technology
Xi'an Jiaotong University

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

45 Scopus citations

Abstract

The great progress in material science and nano-micro fabrication enables the applications of metamaterials with well-defined and well-organized microstructures for noise reduction. However, what intrinsic morphology of the metamaterial would result in optimum sound absorbing efficiency remains uncertain. This work presents a microlattice metamaterial, comprising well-defined and organized material morphology in terms of pore size and porosity, for generating optimum sound dissipation. A compact governing equation is established and verified experimentally to show that the optimum sound absorption can only be reached when the pore size equals twice the thickness of a viscous boundary layer.

Original language	English
Pages (from-to)	EL138-EL143
Journal	Journal of the Acoustical Society of America
Volume	144
Issue number	2
DOIs	https://doi.org/10.1121/1.5051526
State	Published - 1 Aug 2018
Externally published	Yes

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10.1121/1.5051526

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abstract = "The great progress in material science and nano-micro fabrication enables the applications of metamaterials with well-defined and well-organized microstructures for noise reduction. However, what intrinsic morphology of the metamaterial would result in optimum sound absorbing efficiency remains uncertain. This work presents a microlattice metamaterial, comprising well-defined and organized material morphology in terms of pore size and porosity, for generating optimum sound dissipation. A compact governing equation is established and verified experimentally to show that the optimum sound absorption can only be reached when the pore size equals twice the thickness of a viscous boundary layer.",

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AB - The great progress in material science and nano-micro fabrication enables the applications of metamaterials with well-defined and well-organized microstructures for noise reduction. However, what intrinsic morphology of the metamaterial would result in optimum sound absorbing efficiency remains uncertain. This work presents a microlattice metamaterial, comprising well-defined and organized material morphology in terms of pore size and porosity, for generating optimum sound dissipation. A compact governing equation is established and verified experimentally to show that the optimum sound absorption can only be reached when the pore size equals twice the thickness of a viscous boundary layer.

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Sound absorption by acoustic microlattice with optimized pore configuration

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