Extraordinary Sound Screening in Perforated Plates

Estrada, Héctor; Candelas, Pilar; Rubio, Constanza; Belmar, Francisco; Abajo, F. Javier García de; Meseguer, F.

doi:10.1103/physrevlett.101.084302

Cited by 134 publications

(130 citation statements)

References 26 publications

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“…This discrepancy originates in the effect of finite impedance ratio between the plate and the fluid. 18,19 The transmission spectrum for t = 5 mm follows quite closely the prediction of the hard-solid model.Differences between square and triangular lattices can be clearly seen by comparing their respective spectra. The positions of the Wood anomaly ͑vertical arrows in Fig.…”

supporting

confidence: 49%

“…The transmission is dipped right at the Wood anomalies. 19 Comparison between results obtained for both lattices leads to the following conclusions:…”

mentioning

confidence: 95%

“…10,11,16,17 Also, sound can be extraordinarily shielded near the onset of diffraction. 18 Furthermore, intrinsic acoustic modes ͑Lamb and Scholte-Stoneley waves͒ are conspicuous in thin plates, quite different from optics. 19 Finally, we have recently shown 18 that perforated plates are highly transparent to sound for both periodic and random distributions of holes.…”

mentioning

confidence: 99%

“…In order to perform ultrasonic transmission measurements, we use the well-known ultrasonic immersion technique. 18 The angle of incidence is varied by rotating the plate sample from 0°to 60°in steps of 1°. Moreover, we calculate transmission intensities by rigorously solving the sound wave equation within a hard-solid model, 18 in which infinite impedance mismatch between the fluid and the plate is assumed.…”

mentioning

confidence: 99%

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Influence of lattice symmetry on ultrasound transmission through plates with subwavelength aperture arrays

Estrada

Candelas

Rubio

et al. 2009

Applied Physics Letters

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We study the transmission of sound waves through aluminum plates perforated with square and triangular hole arrays. We demonstrate both theoretically and experimentally that lattice symmetry affects the position of the Wood anomalies and the width of the transmission peaks. The angle and frequency dependence of sound transmission through perforated plates are thoroughly discussed. Finally, we observe unexpected anisotropic behavior in the long-wavelength Lamb-mode bands of perforated plates. © 2009 American Institute of Physics. ͓DOI: 10.1063/1.3196330͔Artificial metamaterial structures can exhibit extraordinary properties that are not found in naturally occurring systems. For example, photonic 1 and phononic 2 crystals can block the propagation of light and sound within frequency band gap regions. Other astonishing properties such as negative refraction have been recently demonstrated. 3 In this context, much attention has been paid to metallic membranes perforated with subwavelength periodic hole arrays, 4-6 for which extraordinary optical transmission ͑EOT͒ has been observed, in contrast to the poor transmission of individual apertures. 7 The last decade has witnessed many efforts intended to clarify the physical origin and the interpretation of EOT, as well as to explore applications to sensing and optical processing. 8,9 The comparison between optics and acoustics has undergone successive revision after it was first discussed in the nineteenth century. [10][11][12] Recently, some of the ideas developed for electromagnetic waves have been transferred to acoustics, [13][14][15][16] emphasizing the similarities between subwavelength transmission in both cases. [13][14][15] However, intrinsic differences separate the two kinds of waves. For example, and in contrast to optics, acoustic waves do not present a cutoff wavelength for the existence of guided modes. 10,11,16,17 Also, sound can be extraordinarily shielded near the onset of diffraction. 18 Furthermore, intrinsic acoustic modes ͑Lamb and Scholte-Stoneley waves͒ are conspicuous in thin plates, quite different from optics. 19 Finally, we have recently shown 18 that perforated plates are highly transparent to sound for both periodic and random distributions of holes.In this letter, we study sound transmission through periodically perforated plates with square and triangular distributions of holes, using both theory and experiment. The plates are immersed in water. The periodic structures considered here consist of square and triangular periodic arrangements of circular holes, drilled on 200-mm-wide, 350-mmlong aluminum plates. The holes have a diameter d = 3 mm. Both square and triangular lattices have a period a = 5 mm.Three different plate thicknesses are investigated: t =2, 3, and 5 mm. In order to perform ultrasonic transmission measurements, we use the well-known ultrasonic immersion technique. 18 The angle of incidence is varied by rotating the plate sample from 0°to 60°in steps of 1°. Moreover, we calculate transmission intensities by rigorously solv...

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supporting

confidence: 49%

“…The transmission is dipped right at the Wood anomalies. 19 Comparison between results obtained for both lattices leads to the following conclusions:…”

mentioning

confidence: 95%

mentioning

confidence: 99%

mentioning

confidence: 99%

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Influence of lattice symmetry on ultrasound transmission through plates with subwavelength aperture arrays

Estrada

Candelas

Rubio

et al. 2009

Applied Physics Letters

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“…Estrada et al [16] reported that periodically perforated aluminium plates immersed in water can achieve lower ultrasonic transmission values than homogeneous plates. The influence of the filling fraction of holes and the lattice geometry in the transmission properties has also been studied [17,18].…”

Section: Introductionmentioning

confidence: 99%

A comprehensive discrete-time computer modeling of acoustic Transmission Line loudspeakers

2011

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Multilateral Sound Manipulation Using Magnetically Tunable Apertures

Bansal,

Choi,

Subramanian

2024

Adv Eng Mater

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In recent years, planar aperture‐based acoustic devices have been investigated due to their thin form factor, high effective transmission, and sound modulation capability. Moreover, reconfigurable, and tunable devices are being continuously researched to enable multiple degrees of freedom in real‐time. Here, we present an aperture‐based acoustic device that enables tunable multilateral ultrasonic operation. Sound waves are manipulated in multiple directions by continuously tuning aperture width or length, using a magnetically controlled rod. We exploit the position, orientation, and geometrical properties of the rod (i.e., length, topographical curvature) to create a varied interface for the impinging sound. Through experiments and simulations, we demonstrate acoustic wave steering in different orthogonal planes and acoustic switching using a single tunable device unit. Furthermore, we implement different four‐unit device configurations for tunable beam‐formation and tunable acoustic focusing applications by utilizing the acoustic anisotropy of our system. Our tunable dynamic acoustic device is scalable to audible frequencies and enables tilted operation. This straightforward and accessible proof‐of‐concept opens a paradigm for exploring multifunctional aperture‐based designs with greater degrees of freedom, bringing us a step closer towards practical applications such as acoustic device integration with walls, window panels, and other commercial products for tunable sound transmission.This article is protected by copyright. All rights reserved.

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Extraordinary Sound Screening in Perforated Plates

Cited by 134 publications

References 26 publications

Influence of lattice symmetry on ultrasound transmission through plates with subwavelength aperture arrays

Influence of lattice symmetry on ultrasound transmission through plates with subwavelength aperture arrays

A comprehensive discrete-time computer modeling of acoustic Transmission Line loudspeakers

Multilateral Sound Manipulation Using Magnetically Tunable Apertures

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