• صفحه اصلی
  • Arbitrary Angle Waveguide Bends Made of a New Heterostructure Phononic Crystal

اشتراک گذاری

آدرس مقاله


کد مقاله : JSM-2210-1752 (R1) بازدید : 171 صفحه: 217 - 224

https://doi.org/10.60664/jsm.2023.2101752

20.1001.1.20083505.2023.15.2.7.6

نوع مقاله: پژوهشی

Arbitrary Angle Waveguide Bends Made of a New Heterostructure Phononic Crystal

محورهای موضوعی : Mechanics of Solids

Mohammad Bagherinouri 1 , M Moradi 2

1 - Faculty of Engineering, Arak University, Arak, Iran
2 - Department of Mechanical Engineering, Isfahan University of Technology, Isfahan, Iran

تاریخ دریافت : 1401/12/29 تاریخ پذیرش : 1402/02/20 تاریخ انتشار : 1402/03/11

کلید واژه: Heterostructure, Arbitrary angle waveguide bends, Phononic crystal,

چکیده مقاله :

In this paper, an arbitrary angle waveguide bend made of a new heterostructure phononic crystal has been studied. By creation of line defects in the proposed heterostructure which is composed of square and rhombus phononic crystals, a simple structure waveguide bend with arbitrary angles is made. Analyzing the proposed bend showed that by creating line defects in the composition of the square and equilateral triangle lattices, 30˚ waveguide bend can be realized. Also the study showed that by creating line defects in the composition of the square and rhombus lattices, 40˚ (20˚) waveguide bend could be obtained if the angular constant of the rhombus lattice is 80˚ (40˚). The 40˚ and 20˚ waveguide bends have a narrow pass band which can be utilized as a filter to separate a specific frequency and guide it along a defined pass. Also the study shows that by incorporation of 90˚ bend within the presented heterostructure bends, waveguide bends can be realized that guide elastic waves in the arbitrary angles greater than 90˚.

چکیده انگلیسی:

In this paper, an arbitrary angle waveguide bend made of a new heterostructure phononic crystal has been studied. By creation of line defects in the proposed heterostructure which is composed of square and rhombus phononic crystals, a simple structure waveguide bend with arbitrary angles is made. Analyzing the proposed bend showed that by creating line defects in the composition of the square and equilateral triangle lattices, 30˚ waveguide bend can be realized. Also the study showed that by creating line defects in the composition of the square and rhombus lattices, 40˚ (20˚) waveguide bend could be obtained if the angular constant of the rhombus lattice is 80˚ (40˚). The 40˚ and 20˚ waveguide bends have a narrow pass band which can be utilized as a filter to separate a specific frequency and guide it along a defined pass. Also the study shows that by incorporation of 90˚ bend within the presented heterostructure bends, waveguide bends can be realized that guide elastic waves in the arbitrary angles greater than 90˚.

منابع و مأخذ:


  1. Pennec, Vasseur O., Djafari-Rouhani J., Dobrzyński B., Deymier A. , 2010, Two-dimensional phononic crystals: Examples and applications, Surface Science Reports 65: 229-291.
    2.
  2. Khelif A., Adibi ‎, 2015, Phononic Crystals: Fundamentals and Applications, Springer.
    3.
  3. Alrowaili Z.A., 2023, Locally resonant porous phononic crystal sensor for heavy metals detection: A new approach of highly sensitive liquid sensors, Journal of Molecular Liquids 369: 120964.
    4.
  4. Gueddida A., 2023, Phononic crystal made of silicon ridges on a membrane for liquid sensing, Sensors 23: 2080.
    5.
  5. Gantasala S., 2023, Enhanced piezoelectric energy harvesting based on sandwiched phononic crystal with embedded spheres, Physica Scripta 98: 035029.
    6.
  6. Zhang B., 2021, Application of phononic crystals for vibration reduction and noise reduction of wheel-driven electric buses based on neural networks, Proceedings of the Institution of Mechanical Engineers, Part D: Journal of Automobile Engineering 236(7): 1619-1627.
    7.
  7. Xudong , 2019, Vibration reduction of car body based on 2D dual-base locally resonant phononic crystal, Applied Acoustics 151: 1-9.
    8.
  8. Yongdu, 2021, Isolating low-frequency vibration from power systems on a ship using spiral phononic crystals, Ocean Engineering 225: 108804.
    9.
  9. Yu H., 2021, Phononic band gap and free vibration analysis of fluid-conveying pipes with periodically varying cross-section, Applied Sciences 11: 10485.
    10.
  10. Albino , Godinho L., Amado-Mendes P., Alves-Costa P. , Dias-da-Costa D., Soares Jr D., 2019, 3D FEM analysis of the effect of buried phononic crystal barriers on vibration mitigation, Engineering Structures 196: 109340.
    11.
  11. Gueddida A., 2020, Numerical analysis of a tubular phononic crystal sensor, 2020  IEEE Sensors, Rotterdam, Netherlands.
    12.
  12. Mehaney A., 2022, Hydrostatic pressure effects for controlling the phononic band gap properties in a perfect phononic crystal, Optical and Quantum Electronics 54: 94.
    13.
  13. Djafari-Rouhani B., 2008, Absolute band gaps and waveguiding in free standing and supported phononic crystal slabs, Photonic Nanosrtuct 6: 32-37.
    14.
  14. Jia Z., Chen Y., Yangm H., Wang L., 2018, Designing phononic crystals with wide and robust band gaps, Physical Review Applied 9: 044021.
    15.
  15. Shaobo Z., Liu J., Zhang H., Wang S., 2021, Tunable low frequency band gap and waveguide of phononic crystal plates with different filling ratio, Crystals 11: 828.
    16.
  16. Laud V., 2021, Principles and properties of phononic crystal waveguides, APL Materials 9: 080701.
    17.
  17. Khelif , 2002, Transmittivity through straight and stublike waveguides in a two-dimensional phononic crystal, Physical Review B 65: 174308.
    18.
  18. Khelif A., Choujaa A., Benchabane S., 2004, Guiding and bending of acoustic waves in highly confined phononic crystal waveguides, Applied Physics Letters 84: 4400-4402.
    19.
  19. Salman A., Kaya A., Cicek, 2014, Determination of concentration of ethanol in water by a linear waveguide in a 2-dimensional phononic crystal slab, Sensors and Actuators A: Physical 208: 50-55.
    20.
  20. Kafesaki , Sigalas M. M.,  García  N., 2000,  Frequency modulation in the transitivity of wave guides in elastic-wave band-gap materials, Physical Review Letters 85: 4044,.
    21.
  21. Khelif , Djafari-Rouhani  B., Vasseur J.O., Deymier  P.A., 2003, Transmission and dispersion relations of perfect and defect-containing waveguide structures in phononic band gap materials, Physical Review B 68: 024302.
    22.
  22. Benchabane S., Khelif A., Choujaa A., Djafari-Rouhani B., Laude V., 2005, Interaction of waveguide and localized modes in a phononic crystal, Europhysics Letters 71: 570-575.
    23.
  23. Mohammadi S., Adibi A., 2011, On chip complex signal processing devices using coupled phononic crystal slab resonators and waveguides, AIP Advances 1: 041903.
    24.
  24. Yang X., Zhong J., Xiang J.,  2022, Optimization scheme for piezoelectric energy harvesting in line-defect for 2D starlike hole-type phononic crystals considering waveguides, AIP Advances 12: 015012.
    25.
  25. Guo, Schubert M., Dekorsy T., 2016, Finite element analysis of surface modes in phononic crystal waveguides, Journal of Applied Physics 119: 124302.
    26.
  26. Korozlu N., Biçer A., Sayarcan D., Adem K., Cicek O., 2022, Acoustic sorting of airborne particles by a phononic crystal waveguide, Ultrasonics 124: 106777.
    27.
  27. Yao Y.W., Wu F.G., Hou Z.L., Liu Y.Y., 2007, Propagation properties of elastic waves in semi-infinite phononic crystals and related waveguides, European Physical Journal B 58: 353-360.
    28.
  28. Yao Y.W., Hou Z.L., Liu Y.Y., 2006, The propagating properties of the hetero-structure phononic waveguide, Journal of Physics D: Applied Physics 39: 5164-5168.
    29.
  29. Zarbakhsh J., Hagmann F., Mingaleev S.F., Busch K., Hingerl K., 2004, Arbitrary angle waveguiding applications of two-dimensional curvilinear-lattice photonic crystals, Applied Physics Letters 84: 4687-4689.
    30.
  30. Horiuchi N., Segawa Y., Nozokido T., Mizuno K., Miyazaki H., 2005, High-transmission waveguide with a small radius of curvature at a bend fabricated by use of a circular photonic crystal, Optics Letters 30: 973-975.
    31.
  31. Zhang Y., Li B., 2008, Arbitrary angle waveguide bends in two-dimensional photonic crystals, Optics Communications 281: 4307-4311.
    32.
  32. Li H., Zhang L.H., Chen Y.Q., Feng T.H., Jiang H.T.,Chen H., 2014, Arbitrary angle waveguide bends based on zero-index Metamaterials, Applied Physics A 117: 1541-1545.
    33.
  33. Chen Y.Y., Huang G.L., 2015, Active elastic metamaterials for subwavelength wave propagation control, Acta Mechanica Sinica 31: 349-363.
    34.
  34. Bagherinouri , Moradi M., 2016, Presentation and investigation of a new two dimensional heterostructure phononic crystal to obtain extended band gap, Physica B 489: 28-32.
    35.
  35. Chew W.C., Liu Q.H., 1996, Perfectly matched layers for elastodynamics: A new absorbing boundary condition, Journal of Computational Acoustics 4: 341-359.
    36.

سکوی نشر دانش

سند یا سکوی نشر دانش ،سامانه ای جهت مدیریت حوزه علمی و پژوهشی نشریات دانشگاه آزاد می باشد

پیوندهای سایت

مراکز مرتبط

پشتیبانی

صفحات رسمی

حقوق این وب‌سایت متعلق به سامانه مدیریت نشریات دانشگاه آزاد اسلامی است.
حق نشر © 1403-1400

صفحه اصلی| عضویت/ ورود| درباره سند| تماس با ما|
[English] [العربية] [en] [ar]