Tuning characteristic of band gap and waveguide in a multi-stub locally resonant phononic crystal plate

Wang, Xiaopeng; Jiang, Ping; Chen, Tianning; Zhu, Jian

doi:10.1063/1.4935067

Cited by 29 publications

(16 citation statements)

References 35 publications

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“…5b. In comparison to previous cavity designs reported in the literature and using similar calculation method [2,6,7], the proposed structure enables to achieve the much higher Q factor with minimal phononic crystal size.…”

mentioning

confidence: 93%

“…The acoustic energy with frequencies in the band gaps may be localised in the defect and therefore the propagation can be engineered. In the case of locally resonant structural unit cells, the phononic crystals can exhibit band gaps with a lattice constant smaller than the relevant wavelength [4][5][6][7]. The eigenfrequencies of the localised modes generally depend on the precise geometrical properties (such as size or shape) and the composition of the supporting structure.…”

mentioning

confidence: 99%

“…The eigenfrequencies of the localised modes generally depend on the precise geometrical properties (such as size or shape) and the composition of the supporting structure. Many authors have studied the defect states in such phononic crystals and demonstrated their usefulness as waveguides, filters, and cavity modes [6,7].…”

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confidence: 99%

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Acoustic isolation of disc‐shaped modes using periodic corrugated plate‐based phononic crystal

et al. 2018

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The properties of highly confined and isolated surface modes in a phononic crystal based on a stripped membrane combined with discshaped thin films deposited on the micro-strip surface is investigated. The structure is made of an aluminium nitride (AlN) thin film membrane and gold (Au) for the disc-shaped thin film. These materials are chosen owing to the strong contrast in their elastic and density properties and to their compatibility with electroacoustic devices technology. An optimal choice of the geometrical parameters of the membrane and the grooves enables the obtaining of wide stop-band frequencies. The introduction of disc-shaped thin films on the grooved surface enables the introduction of nearly flat modes within the band gap and consequently paves the way to implement advanced design of electroacoustic filters and high-performance cavity resonators.

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confidence: 93%

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confidence: 99%

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Acoustic isolation of disc‐shaped modes using periodic corrugated plate‐based phononic crystal

et al. 2018

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“…Many authors have studied the defect states in such phononic crystals and demonstrated their usefulness as waveguides, filters, and cavity modes. [23][24][25][26][27][28][29][30][31][32][33][34][35][36] In a recent paper, 37 we have proposed a phononic crystal based on 1D grooves placed periodically in one direction and surmounted by disc shaped thin metallic films deposited periodically on each groove. This platform enabled us to obtain highly confined disc shaped radial contour modes, characterized by their high Q factor and surface mode nature.…”

Section: Introductionmentioning

confidence: 99%

Highly confined radial contour modes in phononic crystal plate based on pillars with cap layers

Moutaouekkil

Talbi

Boudouti³

et al. 2019

Journal of Applied Physics

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We investigate highly confined and isolated surface modes in a phononic crystal plate based on pillars with cap layers. The structure is made of a thin membrane supporting periodic pillars each composed of one cylinder surmounted by a disk shaped cap layer. An optimal choice of the geometrical parameters and material composition allows the structure to support isolated radial contour modes confined in the cap layer. In this study, we consider diamond and gold (Au) as the pillar and cap layers, respectively, and aluminum nitride as a thin membrane owing to the strong contrast in their elastic and density properties and to their compatibility with the integrated circuit technology and microwave electroacoustic devices. The phononic crystal based on diamond pillars allows us to induce a wide stop band frequency, and the addition of the Au disk shaped layer on diamond pillars enables us to introduce flat modes within the bandgap. We demonstrate that one can optimize the flat mode frequencies by varying the geometrical parameters of the Au cap layer. The quality factor (Q) of a cavity resonator composed of one line gold/diamond pillar surrounded by an array of diamond pillars on both sides has been investigated. These results clearly show that, using this design approach, one can (i) reduce the acoustic energy leakage out of the resonator and (ii) optimize the cavity resonator’s Q factor by varying only the geometrical parameters of the gold cap layer. The proposed design provides a promising solution for advanced signal processing and sensing applications.

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“…With the modification of Newton’s second law 14 , the periodic elastic composite may be homogenized and designed to exhibit frequency dependent effective properties 15 , 16 . Those effective properties lead to efficient wave manipulation and result in applications such as enhanced wave damping 17 , wave guides 18 , noise filters 19 and cloaking 20 , 21 .…”

Section: Introductionmentioning

confidence: 99%

Emergent wave phenomena in coupled elastic bars: from extreme attenuation to realization of elastodynamic switches

Chen

Elbanna

2017

Sci Rep

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Metamaterials with acoustic and elastic band gaps are of great interest to scientists and engineers. Here, we introduce a novel mechanism for emergence of multiple band gaps with extreme attenuation by coupling continuous one-dimensional elastic structures. We show that it is possible to develop extreme attenuation at several frequencies from coupling two homogenous bars of different elastodynamic properties even though each bar individually possesses no such gaps. Moreover, if each bar is a composite on its own, multiple resonant band gaps appear in the compound system which do not exist in either bar. We verify our results by conducting numerical simulations for the elastodynamic response and show that the resonant gaps are efficient in attenuating wave propagation. Furthermore, we show that by carefully tailoring the properties of the coupled bars we may construct elastodynamic signal choppers. These results open a new gate for designing Metamaterial with unique wave modulation properties.

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Tuning characteristic of band gap and waveguide in a multi-stub locally resonant phononic crystal plate

Cited by 29 publications

References 35 publications

Acoustic isolation of disc‐shaped modes using periodic corrugated plate‐based phononic crystal

Acoustic isolation of disc‐shaped modes using periodic corrugated plate‐based phononic crystal

Highly confined radial contour modes in phononic crystal plate based on pillars with cap layers

Emergent wave phenomena in coupled elastic bars: from extreme attenuation to realization of elastodynamic switches

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