Bimodal hybrid lightweight sound-absorbing material with high stiffness

Ju Qi Ruan; Shahrzad Ghaffari Mosanenzadeh; Xin Li; Si Yuan Yu; Chu Ma; Xin Lin; Shan Tao Zhang; Ming Hui Lu; Nicholas X. Fang; Yan Feng Chen

doi:10.7567/1882-0786/ab009e

Bimodal hybrid lightweight sound-absorbing material with high stiffness

Ju Qi Ruan, Shahrzad Ghaffari Mosanenzadeh, Xin Li, Si Yuan Yu, Chu Ma, Xin Lin, Shan Tao Zhang, Ming Hui Lu, Nicholas X. Fang, Yan Feng Chen

School of Materials Sience and Engineering

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

8 Scopus citations

Abstract

An iron foam/silica aerogel composite (IFSA) with bimodal structure was designed and fabricated to solve the contradictions between acoustic damping and mechanical strength of a material. IFSA exhibits excellent broadband sound absorption performance with average absorption of ∼57% (500-6400 Hz) and maximum absorption coefficient of 0.995 at 4336 Hz, and high specific stiffness (1.6 ×10⁵ m² s^-2). The dissipation mechanism of sound energy in IFSA is well predicted by a designed bimodal model. Such fascinating artificial composite not only provides new insights for developing structural materials with high noise reduction and strength, but also has great potential applications for various fields.

Original language	English
Article number	035002
Journal	Applied Physics Express
Volume	12
Issue number	3
DOIs	https://doi.org/10.7567/1882-0786/ab009e
State	Published - Mar 2019

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title = "Bimodal hybrid lightweight sound-absorbing material with high stiffness",

abstract = "An iron foam/silica aerogel composite (IFSA) with bimodal structure was designed and fabricated to solve the contradictions between acoustic damping and mechanical strength of a material. IFSA exhibits excellent broadband sound absorption performance with average absorption of ∼57% (500-6400 Hz) and maximum absorption coefficient of 0.995 at 4336 Hz, and high specific stiffness (1.6 ×105 m2 s-2). The dissipation mechanism of sound energy in IFSA is well predicted by a designed bimodal model. Such fascinating artificial composite not only provides new insights for developing structural materials with high noise reduction and strength, but also has great potential applications for various fields.",

author = "Ruan, {Ju Qi} and Mosanenzadeh, {Shahrzad Ghaffari} and Xin Li and Yu, {Si Yuan} and Chu Ma and Xin Lin and Zhang, {Shan Tao} and Lu, {Ming Hui} and Fang, {Nicholas X.} and Chen, {Yan Feng}",

note = "Publisher Copyright: {\textcopyright} 2019 The Japan Society of Applied Physics.",

year = "2019",

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doi = "10.7567/1882-0786/ab009e",

language = "英语",

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TY - JOUR

T1 - Bimodal hybrid lightweight sound-absorbing material with high stiffness

AU - Ruan, Ju Qi

AU - Mosanenzadeh, Shahrzad Ghaffari

AU - Li, Xin

AU - Yu, Si Yuan

AU - Ma, Chu

AU - Lin, Xin

AU - Zhang, Shan Tao

AU - Lu, Ming Hui

AU - Fang, Nicholas X.

AU - Chen, Yan Feng

PY - 2019/3

Y1 - 2019/3

N2 - An iron foam/silica aerogel composite (IFSA) with bimodal structure was designed and fabricated to solve the contradictions between acoustic damping and mechanical strength of a material. IFSA exhibits excellent broadband sound absorption performance with average absorption of ∼57% (500-6400 Hz) and maximum absorption coefficient of 0.995 at 4336 Hz, and high specific stiffness (1.6 ×105 m2 s-2). The dissipation mechanism of sound energy in IFSA is well predicted by a designed bimodal model. Such fascinating artificial composite not only provides new insights for developing structural materials with high noise reduction and strength, but also has great potential applications for various fields.

AB - An iron foam/silica aerogel composite (IFSA) with bimodal structure was designed and fabricated to solve the contradictions between acoustic damping and mechanical strength of a material. IFSA exhibits excellent broadband sound absorption performance with average absorption of ∼57% (500-6400 Hz) and maximum absorption coefficient of 0.995 at 4336 Hz, and high specific stiffness (1.6 ×105 m2 s-2). The dissipation mechanism of sound energy in IFSA is well predicted by a designed bimodal model. Such fascinating artificial composite not only provides new insights for developing structural materials with high noise reduction and strength, but also has great potential applications for various fields.

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DO - 10.7567/1882-0786/ab009e

M3 - 文章

AN - SCOPUS:85063343658

SN - 1882-0778

VL - 12

JO - Applied Physics Express

JF - Applied Physics Express

IS - 3

M1 - 035002

ER -

Bimodal hybrid lightweight sound-absorbing material with high stiffness

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