Influence of the Core Pillar Height on the Bandgap Characteristics of Piezoelectric Phononic Crystals with Ring-Shaped Grooves

Furkan Kuruoğlu

doi:10.17776/csj.1104315

Araştırma Makalesi

Influence of the Core Pillar Height on the Bandgap Characteristics of Piezoelectric Phononic Crystals with Ring-Shaped Grooves

Yıl 2022, Cilt: 43 Sayı: 2, 346 - 350, 29.06.2022

Furkan Kuruoğlu

https://doi.org/10.17776/csj.1104315

Öz

Dispersion profiles and surface acoustic wave attenuation characteristics of ring-shaped phononic crystals are investigated as a function of the core pillar height. Finite element method simulations are carried out for both band analyses and transmission spectra calculations. The results reveal that increasing core pillar height results in a decrement in the local resonance band frequency and the corresponding transmission peaks. The obtained dispersion profiles show that the phononic crystal bandgap also expands from 6 MHz to 11 MHz while the pillar height increases from 5 um to 7 um. Similar characteristics are also seen in the transmission spectra for the varying core pillar heights of the ring-shaped periodic grooves. In addition, surface acoustic wave attenuation competency depends on the core pillar height. The frequencies where the investigated phononic crystals are functional can be tuned by adjusting the core pillar height.

Anahtar Kelimeler

Surface acoustic wave, Phononic crystal, Finite element method, Phononic bandgap.

Proje Numarası

120F337

Kaynakça

[1] Collins D.J., Devendran C., Ma Z., Ng, J.W., Neild A., Ai Y., Acoustic tweezers via sub–time-of-flight regime surface acoustic waves, Sci. Adv., 2 (7) (2016) e1600089.
[2] Topaltzikis D., Wielunski M., Hörner A.L., Küß M., Reiner A., Grünwald T., Schreck M., Wixforth A., Rühm W., Detection of x rays by a surface acoustic delay line in contact with a diamond crystal, Appl. Phys. Lett., 118 (13) (2021) 133501.
[3] Su R., Shen J., Lu Z., Xu H., Niu Q., Xu Z., Zeng F., Song C., Wang W., Fu S., Pan F., Wideband and Low-Loss Surface Acoustic Wave Filter Based on 15° YX-LiNbO₃/SiO₂/Si Structure, IEEE Electr. Device L., 42 (3) (2021) 438-441.
[4] Su R., Fu S., Shen J., Lu Z., Xu H., Yang M., Zeng F., Song C., Wang W., Pan F., Power Durability Enhancement and Failure Analysis of TC-SAW Filter With Ti/Cu/Ti/Cu/Ti Electrodes, IEEE T. Device Mat. Re., 21 (3) (2021) 365-371.
[5] Xie Y., Mao Z., Bachman H., Li P., Zhang P., Ren L., Wu M., Huang T.J., Acoustic Cell Separation Based On Biophysical Properties., J. Biomechanical Eng., 142 (3) (2020) 031005-1-9.
[6] Qian J., Ren J., Liu Y., Lam R.H.W., Lee J.E.-Y., A two-chip acoustofluidic particle manipulation platform with a detachable and reusable surface acoustic wave device, Analyst, 145 (23) (2020) 7752-7758.
[7] Agostini M., Greco G., Cecchini M., Full-SAW Microfluidics-Based Lab-on-a-Chip for Biosensing, IEEE Access, 7 (2019) 70901-70909.
[8] Kumar A., Prajesh R., The Potential of Acoustic Wave Devices for Gas Sensing Applications, Sens. Actuator A-Phys. Physical, 339 (2022) 113498.
[9] Hekiem N.L.L., Ralib A.A.M., Hattar M.A. bt M., Ahmad F., Nordin A.N., Rahim,R.A., Za’bah,N.F., Advanced vapour sensing materials, Existing and latent to acoustic wave sensors for VOCs detection as the potential exhaled breath biomarkers for lung cancer, Sens. Actuator A-Phys., 329 (2021) 112792.
[10] Wang Y., Wang,., Liu, W., Chen D., Wu C., Xie J., An aerosol sensor for PM1 concentration detection based on 3D printed virtual impactor and SAW sensor, Sens. Actuator A-Phys., 288 (2019) 67-74.
[11] Zhang X.-F., Zhang Z.-W., He Y.-L., Liu Y.-X., L, S., Fang J.-Y., Zhang X.-A., Peng G., Sniffing lung cancer related biomarkers using an oxidized graphene SAW sensor Frontiers of Physics, 11 (2015) 2.
[12] Kidakova A., Boroznjak R., Reut J., Öpik A., Saarma M., Syritski V., Molecularly imprinted polymer-based SAW sensor for label-free detection of cerebral dopamine neurotrophic factor protein, Sens. Actuator B-Chem., 308 (2020) 127708.
[13] Kushwaha M.S., Halevi P., Martínez G., Dobrzynski L., Djafari-Rouhani, B., Theory of acoustic band structure of periodic elastic composites Phys. Rev. B, 49 (4) (1994) 2313-2322.
[14] Sigalas M., Economou, E.N., Band structure of elastic waves in two dimensional systems, Solid State Commun., 86 (3) (1993) 141-143.
[15] Mead D.M., Wave Propagatıon In Contınuous Perıodıc Structures, Research Contrıbutıons From Southampton, 1964–1995, J.Sound Vibr., 190 (3) (1996) 495-524.
[16] Kushwaha M.S., Halevi P., Dobrzynski L., Djafari-Rouhani B., Acoustic band structure of periodic elastic composites, Phys.Rev. Lett., 71 (13) (1993) 2022-2025.
[17] Achaoui Y., Khelif A., Benchabane S., Robert L., Laude V., Experimental observation of locally-resonant and Bragg band gaps for surface guided waves in a phononic crystal of pillars, Phys. Rev. B, 83 (10) (2011) 104201.
[18] Achaoui Y., Laude V., Benchabane S., Khelif A., Local resonances in phononic crystals and in random arrangements of pillars on a surface, J. Appl. Phys .114 (10) (2013) 104503.
[19] Jin Y., Pennec Y., Bonello B., Honarvar H., Dobrzynski L., Djafari-Rouhani B., Hussein M.I., Physics of surface vibrational resonances, pillared phononic crystals, metamaterials, and metasurfaces, Rep. Prog. Phys., 84 (8) (2021) 086502.
[20] Vasseur J.O., Hladky-Hennion A.-C., Djafari-Rouhani B., Duval F., Dubus,B., Pennec Y., Deymier P.A., Waveguiding in two-dimensional piezoelectric phononic crystal plates, J. Appl. Phys., 101 (11) (2007) 114904.
[21] Oh J.H., Lee I.K., M, P.S., Kim Y.Y., Active wave-guiding of piezoelectric phononic crystals, Appl. Phys. Lett., 99(8) (2011) 083505.
[22] Zhang Z.-D., Liu F.-K., Yu S.-Y., Lu M.-H, Chen Y.-F., An integrable and configurable phononic beam splitter based on self-collimated surface acoustic waves, Appl. Phys. Express, 13 (4) (2020) 044002.
[23]Schmidt M.-P., Oseev A., Lucklum R., Zubtsov M., Hirsch S., SAW based phononic crystal sensor, technological challenges and solutions, Microsyst. Technol., 22 (7) (2016) 1593-1599.
[24]Gharibi H., Khaligh A., Bahrami A., Ghavifekr H.B., A very high sensitive interferometric phononic crystal liquid sensor, J. Mol. Liq., 296 (2019) 111878.
[25]Gharibi H.,Mehaney A., Two-dimensional phononic crystal sensor for volumetric detection of hydrogen peroxide (H2O2) in liquids, Phys. E Low-dimensional Syst. Nanostructures, 126 (2021) 114429.
[26]Cao D., Hu W., Gao Y., Guo X., Vibration and energy harvesting performance of a piezoelectric phononic crystal beam, Smart Mater. Struct., 28 (8) (2019) 085014.
[27] Bourquin Y., Wilson R., Zhang Y., Reboud J.,Cooper J.M., Phononic Crystals for Shaping Fluids, Adv. Mater., 23 (12) (2011) 1458-1462.
[28]Ash B.J., Worsfold S.R., Vukusic P.,Nash G.R., A highly attenuating and frequency tailorable annular hole phononic crystal for surface acoustic waves, Nature Communications, 8 (1) (2017) 174.
[29]Ozgur Y., Birol O., Dong X., Srinivas S., Conicity and depth effects on the optical transmission of lithium niobate photonic crystals patterned by focused ion beam, Opt. Mater. Express, 1 (7) (2011) 1262-1271.
[30]Levy M., Bass H., Stern R., Modern Acoustical Techniques for the Measurement of Mechanical Properties, Elsevier Science, (2001).
[31] Laurell T., Lenshof A., Microscale Acoustofluidics, Royal Society of Chemistry, (2014).
[32]Berenge, J.-P., Perfectly matched layer for the FDTD solution of wave-structure interaction problems, IEEE T. Antenn. Propag., 44 (1) (1996) 110-117.
[33]Pennec Y., Djafari-Rouhani B., Larabi H., Vasseur J.O., Hladky-Hennion A.C., Low-frequency gaps in a phononic crystal constituted of cylindrical dots deposited on a thin homogeneous plate, Phys. Rev. B, 78 (10) (2008) 104105.

Yıl 2022, Cilt: 43 Sayı: 2, 346 - 350, 29.06.2022

Furkan Kuruoğlu

https://doi.org/10.17776/csj.1104315

Öz

Destekleyen Kurum

Türkiye Bilimsel ve Teknolojik Araştırma Kurumu (TÜBİTAK)

Proje Numarası

120F337

Teşekkür

Prof. Dr. Ahmet Çiçek ve Prof. Dr. Ayşe Erol' a eşsiz katkılarından dolayı teşekkürlerimi sunarım.

Kaynakça

[1] Collins D.J., Devendran C., Ma Z., Ng, J.W., Neild A., Ai Y., Acoustic tweezers via sub–time-of-flight regime surface acoustic waves, Sci. Adv., 2 (7) (2016) e1600089.
[2] Topaltzikis D., Wielunski M., Hörner A.L., Küß M., Reiner A., Grünwald T., Schreck M., Wixforth A., Rühm W., Detection of x rays by a surface acoustic delay line in contact with a diamond crystal, Appl. Phys. Lett., 118 (13) (2021) 133501.
[3] Su R., Shen J., Lu Z., Xu H., Niu Q., Xu Z., Zeng F., Song C., Wang W., Fu S., Pan F., Wideband and Low-Loss Surface Acoustic Wave Filter Based on 15° YX-LiNbO₃/SiO₂/Si Structure, IEEE Electr. Device L., 42 (3) (2021) 438-441.
[4] Su R., Fu S., Shen J., Lu Z., Xu H., Yang M., Zeng F., Song C., Wang W., Pan F., Power Durability Enhancement and Failure Analysis of TC-SAW Filter With Ti/Cu/Ti/Cu/Ti Electrodes, IEEE T. Device Mat. Re., 21 (3) (2021) 365-371.
[5] Xie Y., Mao Z., Bachman H., Li P., Zhang P., Ren L., Wu M., Huang T.J., Acoustic Cell Separation Based On Biophysical Properties., J. Biomechanical Eng., 142 (3) (2020) 031005-1-9.
[6] Qian J., Ren J., Liu Y., Lam R.H.W., Lee J.E.-Y., A two-chip acoustofluidic particle manipulation platform with a detachable and reusable surface acoustic wave device, Analyst, 145 (23) (2020) 7752-7758.
[7] Agostini M., Greco G., Cecchini M., Full-SAW Microfluidics-Based Lab-on-a-Chip for Biosensing, IEEE Access, 7 (2019) 70901-70909.
[8] Kumar A., Prajesh R., The Potential of Acoustic Wave Devices for Gas Sensing Applications, Sens. Actuator A-Phys. Physical, 339 (2022) 113498.
[9] Hekiem N.L.L., Ralib A.A.M., Hattar M.A. bt M., Ahmad F., Nordin A.N., Rahim,R.A., Za’bah,N.F., Advanced vapour sensing materials, Existing and latent to acoustic wave sensors for VOCs detection as the potential exhaled breath biomarkers for lung cancer, Sens. Actuator A-Phys., 329 (2021) 112792.
[10] Wang Y., Wang,., Liu, W., Chen D., Wu C., Xie J., An aerosol sensor for PM1 concentration detection based on 3D printed virtual impactor and SAW sensor, Sens. Actuator A-Phys., 288 (2019) 67-74.
[11] Zhang X.-F., Zhang Z.-W., He Y.-L., Liu Y.-X., L, S., Fang J.-Y., Zhang X.-A., Peng G., Sniffing lung cancer related biomarkers using an oxidized graphene SAW sensor Frontiers of Physics, 11 (2015) 2.
[12] Kidakova A., Boroznjak R., Reut J., Öpik A., Saarma M., Syritski V., Molecularly imprinted polymer-based SAW sensor for label-free detection of cerebral dopamine neurotrophic factor protein, Sens. Actuator B-Chem., 308 (2020) 127708.
[13] Kushwaha M.S., Halevi P., Martínez G., Dobrzynski L., Djafari-Rouhani, B., Theory of acoustic band structure of periodic elastic composites Phys. Rev. B, 49 (4) (1994) 2313-2322.
[14] Sigalas M., Economou, E.N., Band structure of elastic waves in two dimensional systems, Solid State Commun., 86 (3) (1993) 141-143.
[15] Mead D.M., Wave Propagatıon In Contınuous Perıodıc Structures, Research Contrıbutıons From Southampton, 1964–1995, J.Sound Vibr., 190 (3) (1996) 495-524.
[16] Kushwaha M.S., Halevi P., Dobrzynski L., Djafari-Rouhani B., Acoustic band structure of periodic elastic composites, Phys.Rev. Lett., 71 (13) (1993) 2022-2025.
[17] Achaoui Y., Khelif A., Benchabane S., Robert L., Laude V., Experimental observation of locally-resonant and Bragg band gaps for surface guided waves in a phononic crystal of pillars, Phys. Rev. B, 83 (10) (2011) 104201.
[18] Achaoui Y., Laude V., Benchabane S., Khelif A., Local resonances in phononic crystals and in random arrangements of pillars on a surface, J. Appl. Phys .114 (10) (2013) 104503.
[19] Jin Y., Pennec Y., Bonello B., Honarvar H., Dobrzynski L., Djafari-Rouhani B., Hussein M.I., Physics of surface vibrational resonances, pillared phononic crystals, metamaterials, and metasurfaces, Rep. Prog. Phys., 84 (8) (2021) 086502.
[20] Vasseur J.O., Hladky-Hennion A.-C., Djafari-Rouhani B., Duval F., Dubus,B., Pennec Y., Deymier P.A., Waveguiding in two-dimensional piezoelectric phononic crystal plates, J. Appl. Phys., 101 (11) (2007) 114904.
[21] Oh J.H., Lee I.K., M, P.S., Kim Y.Y., Active wave-guiding of piezoelectric phononic crystals, Appl. Phys. Lett., 99(8) (2011) 083505.
[22] Zhang Z.-D., Liu F.-K., Yu S.-Y., Lu M.-H, Chen Y.-F., An integrable and configurable phononic beam splitter based on self-collimated surface acoustic waves, Appl. Phys. Express, 13 (4) (2020) 044002.
[23]Schmidt M.-P., Oseev A., Lucklum R., Zubtsov M., Hirsch S., SAW based phononic crystal sensor, technological challenges and solutions, Microsyst. Technol., 22 (7) (2016) 1593-1599.
[24]Gharibi H., Khaligh A., Bahrami A., Ghavifekr H.B., A very high sensitive interferometric phononic crystal liquid sensor, J. Mol. Liq., 296 (2019) 111878.
[25]Gharibi H.,Mehaney A., Two-dimensional phononic crystal sensor for volumetric detection of hydrogen peroxide (H2O2) in liquids, Phys. E Low-dimensional Syst. Nanostructures, 126 (2021) 114429.
[26]Cao D., Hu W., Gao Y., Guo X., Vibration and energy harvesting performance of a piezoelectric phononic crystal beam, Smart Mater. Struct., 28 (8) (2019) 085014.
[27] Bourquin Y., Wilson R., Zhang Y., Reboud J.,Cooper J.M., Phononic Crystals for Shaping Fluids, Adv. Mater., 23 (12) (2011) 1458-1462.
[28]Ash B.J., Worsfold S.R., Vukusic P.,Nash G.R., A highly attenuating and frequency tailorable annular hole phononic crystal for surface acoustic waves, Nature Communications, 8 (1) (2017) 174.
[29]Ozgur Y., Birol O., Dong X., Srinivas S., Conicity and depth effects on the optical transmission of lithium niobate photonic crystals patterned by focused ion beam, Opt. Mater. Express, 1 (7) (2011) 1262-1271.
[30]Levy M., Bass H., Stern R., Modern Acoustical Techniques for the Measurement of Mechanical Properties, Elsevier Science, (2001).
[31] Laurell T., Lenshof A., Microscale Acoustofluidics, Royal Society of Chemistry, (2014).
[32]Berenge, J.-P., Perfectly matched layer for the FDTD solution of wave-structure interaction problems, IEEE T. Antenn. Propag., 44 (1) (1996) 110-117.
[33]Pennec Y., Djafari-Rouhani B., Larabi H., Vasseur J.O., Hladky-Hennion A.C., Low-frequency gaps in a phononic crystal constituted of cylindrical dots deposited on a thin homogeneous plate, Phys. Rev. B, 78 (10) (2008) 104105.

Toplam 33 adet kaynakça vardır.

Ayrıntılar

Birincil Dil	İngilizce
Konular	Klasik Fizik (Diğer)
Bölüm	Natural Sciences
Yazarlar	Furkan Kuruoğlu 0000-0002-5314-4441
Proje Numarası	120F337
Yayımlanma Tarihi	29 Haziran 2022
Gönderilme Tarihi	16 Nisan 2022
Kabul Tarihi	16 Haziran 2022
Yayımlandığı Sayı	Yıl 2022Cilt: 43 Sayı: 2

Kaynak Göster

APA	Kuruoğlu, F. (2022). Influence of the Core Pillar Height on the Bandgap Characteristics of Piezoelectric Phononic Crystals with Ring-Shaped Grooves. Cumhuriyet Science Journal, 43(2), 346-350. https://doi.org/10.17776/csj.1104315

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