Surface wettability induced variation of underwater acoustic transmission coefficient of the membrane resonators

•Various wettability surfaces were fabricated by laser ablation and chemical modification.•Achieve about 20% of acoustic adjustable range from 28 kHz to 50 kHz.•Tunable transmission coefficient of MR ascribes to the mechanism of various adhesion. The capability to effectively manipulate the transmis...

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Bibliographic Details
Published in:Materials science & engineering. B, Solid-state materials for advanced technology Solid-state materials for advanced technology, 2020-08, Vol.258, p.114572, Article 114572
Main Authors: Feng, Guang, Xue, Yao, Pan, Qiaofei, Ke, Yirui, Li, Fengping, Xue, Wei, Cao, Yu, Liu, Wenwen
Format: Article
Language:English
Subjects:
Acoustic waves
Acoustics
Adhesives
Coefficient of variation
Copper
Hydrophilic
Laser beam texturing
Laser texturing
Membrane resonators
Membranes
Platelets
Resonators
Sound transmission
Superhydrophobic
Texturing
Transmission coefficient
Tunable adhesive force
Underwater acoustics
Underwater communication
Wettability
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Summary:•Various wettability surfaces were fabricated by laser ablation and chemical modification.•Achieve about 20% of acoustic adjustable range from 28 kHz to 50 kHz.•Tunable transmission coefficient of MR ascribes to the mechanism of various adhesion. The capability to effectively manipulate the transmission coefficient is essential to the detection sensitivity of underwater acoustic equipment. Here we present a tunable transmission coefficient of the underwater membrane resonators by adjusting the surface wettability of the copper platelets. The variation of the surface wettability of the copper platelet can be realized by laser texturing and chemical modification, which further induces an alternative adhesive force. When the membrane resonators are penetrated by an acoustic wave underwater, it exhibits modified vibration patterns attributed to the different surface adhesive force of the attached copper platelet. A greater adhesive force of the copper surface leads to a higher transmission coefficient of the membrane resonators. The transmission coefficient can be adjusted in a range of [−12%, 8%] in comparison to the pristine copper surface in accordance to an adhesive force. This work shows excellent potential in underwater sonic sensing and communication.
ISSN:0921-5107
1873-4944
DOI:10.1016/j.mseb.2020.114572