Bubble-type coding metasurfaces for broadband deep subwavelength underwater acoustic manipulations

Ping Han; Zhan Dong Huang; Hao Wen Dong; Sheng Dong Zhao

doi:10.35848/1882-0786/accc6c

Bubble-type coding metasurfaces for broadband deep subwavelength underwater acoustic manipulations

Ping Han, Zhan Dong Huang, Hao Wen Dong^*, Sheng Dong Zhao^*

^*Corresponding author for this work

Institute of Advanced Structure Technology

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

6 Citations (Scopus)

Abstract

We construct a reflective broadband acoustic coding metasurface using bubbles as the unit. The reflected phase difference between the cube bubble unit and the pure water unit is about π over a wide frequency range. The broadband phenomenon could be explained by the reflection theory between the soft water-air interface and the hard water-rigid interface. Its relative bandwidth reaches 187%, close to 200% of the theoretical limit. By reconstructing the 0/1 sequence, we performed numerical simulation on broadband acoustic focusing and diffusing reflection. The research in this work has potential applications in improving the performance of underwater communication and cloaking.

Original language	English
Article number	045505
Journal	Applied Physics Express
Volume	16
Issue number	4
DOIs	https://doi.org/10.35848/1882-0786/accc6c
Publication status	Published - 1 Apr 2023

Keywords

acoustic manipulations
broadband
bubble
metasurface

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10.35848/1882-0786/accc6c

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title = "Bubble-type coding metasurfaces for broadband deep subwavelength underwater acoustic manipulations",

abstract = "We construct a reflective broadband acoustic coding metasurface using bubbles as the unit. The reflected phase difference between the cube bubble unit and the pure water unit is about π over a wide frequency range. The broadband phenomenon could be explained by the reflection theory between the soft water-air interface and the hard water-rigid interface. Its relative bandwidth reaches 187%, close to 200% of the theoretical limit. By reconstructing the 0/1 sequence, we performed numerical simulation on broadband acoustic focusing and diffusing reflection. The research in this work has potential applications in improving the performance of underwater communication and cloaking.",

keywords = "acoustic manipulations, broadband, bubble, metasurface",

author = "Ping Han and Huang, {Zhan Dong} and Dong, {Hao Wen} and Zhao, {Sheng Dong}",

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AU - Han, Ping

AU - Huang, Zhan Dong

AU - Dong, Hao Wen

AU - Zhao, Sheng Dong

PY - 2023/4/1

Y1 - 2023/4/1

N2 - We construct a reflective broadband acoustic coding metasurface using bubbles as the unit. The reflected phase difference between the cube bubble unit and the pure water unit is about π over a wide frequency range. The broadband phenomenon could be explained by the reflection theory between the soft water-air interface and the hard water-rigid interface. Its relative bandwidth reaches 187%, close to 200% of the theoretical limit. By reconstructing the 0/1 sequence, we performed numerical simulation on broadband acoustic focusing and diffusing reflection. The research in this work has potential applications in improving the performance of underwater communication and cloaking.

AB - We construct a reflective broadband acoustic coding metasurface using bubbles as the unit. The reflected phase difference between the cube bubble unit and the pure water unit is about π over a wide frequency range. The broadband phenomenon could be explained by the reflection theory between the soft water-air interface and the hard water-rigid interface. Its relative bandwidth reaches 187%, close to 200% of the theoretical limit. By reconstructing the 0/1 sequence, we performed numerical simulation on broadband acoustic focusing and diffusing reflection. The research in this work has potential applications in improving the performance of underwater communication and cloaking.

KW - acoustic manipulations

KW - broadband

KW - bubble

KW - metasurface

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JO - Applied Physics Express

JF - Applied Physics Express

IS - 4

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ER -

Bubble-type coding metasurfaces for broadband deep subwavelength underwater acoustic manipulations

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Keywords

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