Acoustic Wave Splitting and Wave Trapping Designs

IF 1.9 4区工程技术 Q2 ACOUSTICS

Journal of Vibration and Acoustics-Transactions of the Asme Pub Date : 2022-01-28 DOI:10.1115/1.4053713

Yu-Chi Su, Liwen Ko

引用次数: 0

Abstract

Acoustic metasurfaces use the phase gradient of a single layer to reflect/refract waves in any direction. This study shows that other than wave steering, acoustic metasurfaces can exhibit wave splitting or trapping through the geometry design. Previous studies focused on the generalized Snell's law when developing metasurfaces and attempted to prevent wave leakages. On the contrary, this study exploits the periodicity of metasurfaces to accomplish acoustic wave splitting, which leads to a similar concept to metagrating. For acoustic wave trapping, we show that through proper arrangements, an acoustic wave can be localized in a specific region without using any boundaries based on the generalized Snell's law. A design formula is provided to trap waves from any incident angle or at any frequency. The analytical and numerical results are in good agreement, verifying the effectiveness of the proposed concept for wave splitting and trapping. This study shows the versatile applications of acoustic metasurfaces and is useful for interferometry and energy harvesting.

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声波分裂和波捕获设计

声学超表面利用单层的相位梯度来反射/折射任何方向的波。本研究表明，除了波浪转向外，声学超表面还可以通过几何设计表现出波的分裂或捕获。以往的研究在开发超表面时主要关注广义斯涅尔定律，并试图防止波泄漏。相反，本研究利用超表面的周期性来完成声波分裂，这导致了一个类似于超聚合的概念。对于声波捕获，我们根据广义斯涅尔定律证明，通过适当的排列，声波可以不使用任何边界而定位在特定区域。提供了一个设计公式，可以捕获任何入射角或任何频率的波。分析结果与数值结果吻合较好，验证了所提出的波分裂和捕获概念的有效性。该研究显示了声学超表面的广泛应用，并有助于干涉测量和能量收集。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of Vibration and Acoustics-Transactions of the Asme 工程技术-工程：机械

CiteScore

4.20

自引率

11.80%

发文量

审稿时长

7 months

期刊介绍： The Journal of Vibration and Acoustics is sponsored jointly by the Design Engineering and the Noise Control and Acoustics Divisions of ASME. The Journal is the premier international venue for publication of original research concerning mechanical vibration and sound. Our mission is to serve researchers and practitioners who seek cutting-edge theories and computational and experimental methods that advance these fields. Our published studies reveal how mechanical vibration and sound impact the design and performance of engineered devices and structures and how to control their negative influences. Vibration of continuous and discrete dynamical systems; Linear and nonlinear vibrations; Random vibrations; Wave propagation; Modal analysis; Mechanical signature analysis; Structural dynamics and control; Vibration energy harvesting; Vibration suppression; Vibration isolation; Passive and active damping; Machinery dynamics; Rotor dynamics; Acoustic emission; Noise control; Machinery noise; Structural acoustics; Fluid-structure interaction; Aeroelasticity; Flow-induced vibration and noise.