Simulations of acoustic waves bandgaps in a surface of silicon with a periodic hole structure in a thin nickel film

Graczyk, Piotr; Mróz, B.

doi:10.1063/1.4892076

Cited by 6 publications

(2 citation statements)

References 22 publications

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“…The acoustic wave propagation in the 2D PCs was simulated using FEM with the acoustic module of COMSOL Multiphysics software. 20) The calculated frequency ranges were from 300 to 1300 kHz with 2 kHz intervals. The normal component of the velocity of the water particles is zero on the walls of the rods because reflecting boundary conditions were applied at the interfaces between the stainless-steel rods and water.…”

Section: Numerical and Experimental Methodsmentioning

confidence: 99%

Acoustic band gaps due to diffraction modes in two-dimensional phononic crystals

Kang

Lee

Yoon

2017

Jpn. J. Appl. Phys.

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In this study, we experimentally and theoretically investigated acoustic band gap control with diffraction modes in two-dimensional (2D) phononic crystals (PCs) consisting of periodic arrays of stainless steel (SS) rods immersed in water. We could classify the acoustic band gaps into two types with diffraction modes in the reflection region, and control the center frequencies of the band gaps by varying the vertical lattice constants. Pressure transmission coefficients and acoustic pressure fields were calculated using the finite element method (FEM), to classify and control the acoustic band gaps. As the vertical lattice constants were varied, the center frequencies of the band gaps, where only normal reflection occurred, were almost constant while those of the band gaps, where additional reflected waves with different propagation directions occurred, decreased with increasing the vertical lattice constants. This work can be used to manipulate acoustic band gap adding, splitting, and shifting.

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Section: Numerical and Experimental Methodsmentioning

confidence: 99%

Acoustic band gaps due to diffraction modes in two-dimensional phononic crystals

Kang

Lee

Yoon

2017

Jpn. J. Appl. Phys.

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“…[9] as well as Finite Element (FEM)-based absorbing regions [10,11,12] and Perfectly Matched Layers [13,14], while the so-called Plane Wave Expansion (PWE) method has been used in [15,16,17].…”

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confidence: 99%

Band structure analysis of leaky Bloch waves in 2D phononic crystal plates

Mazzotti¹,

Miniaci²,

Bartoli³

2017

Ultrasonics

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A hybrid Finite Element-Plane Wave Expansion method is presented for the band structure analysis of phononic crystal plates with two dimensional lattice that are in contact with acoustic half-spaces. The method enables the computation of both real (propagative) and imaginary (attenuation) components of the Bloch wavenumber at any given frequency.Three numerical applications are presented: a benchmark dispersion analysis for an oil-loaded Titanium isotropic plate, the band structure analysis of a waterloaded Tungsten slab with square cylindrical cavities and a phononic crystal plate composed of Aurum cylinders embedded in an epoxy matrix.

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Band structure of love wave in a one-dimensional piezoelectric layered phononic crystal with imperfect interface

Yang

Zhang

et al. 2022

Mechanics of Advanced Materials and Structures

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Simulations of acoustic waves bandgaps in a surface of silicon with a periodic hole structure in a thin nickel film

Cited by 6 publications

References 22 publications

Acoustic band gaps due to diffraction modes in two-dimensional phononic crystals

Acoustic band gaps due to diffraction modes in two-dimensional phononic crystals

Band structure analysis of leaky Bloch waves in 2D phononic crystal plates

Band structure of love wave in a one-dimensional piezoelectric layered phononic crystal with imperfect interface

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