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Journal of Synthetic Crystals, Volume. 52, Issue 4, 590(2023)

Bandgaps of a Helmholtz-Type Phononic Crystal with Adjustable Chamber

LIU Hong, ZHAO Jingbo, YAO Hong, HAN Donghai, ZHANG Xiaosheng, WANG Chen, and ZHANG Guangjun
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    [5] [5] SONG Y H, SHEN Y F. A tunable phononic crystal system for elastic ultrasonic wave control[J]. Applied Physics Letters, 2021, 118(22): 224104.

    [6] [6] WU X D, SUN L Z, ZUO S G, et al. Vibration reduction of car body based on 2D dual-base locally resonant phononic crystal[J]. Applied Acoustics, 2019, 151: 1-9.

    [7] [7] XU G G, SUN X W, LI R S, et al. The low-frequency bandgap characteristics of a new three-dimensional multihole phononic crystal[J]. Applied Physics A, 2021, 127(11): 812.

    [8] [8] HAN D H, ZHAO J B, ZHANG G J, et al. Study on low-frequency band gap characteristics of a new Helmholtz type phononic crystal[J]. Symmetry, 2021, 13(8): 1379.

    [14] [14] WANG G, WEN X S, WEN J H, et al. Two-dimensional locally resonant phononic crystals with binary structures[J]. Physical Review Letters, 2004, 93(15): 154302.

    [17] [17] MAHESH K, MINI R S. Investigation on the acoustic performance of multiple Helmholtz resonator configurations[J]. Acoustics Australia, 2021, 49(2): 355-369.

    [19] [19] DUAN H Q, SHEN X M, WANG E S, et al. Acoustic multi-layer Helmholtz resonance metamaterials with multiple adjustable absorption peaks[J]. Applied Physics Letters, 2021, 118(24): 241904.

    [21] [21] GAO N S, WU J H, YU L. Large band gaps in two-dimensional phononic crystals with self-similarity structure[J]. International Journal of Modern Physics B, 2015, 29(4): 1550017.

    [22] [22] GAO N S, WU J H, JING L. Research on the band gaps of the two-dimensional Sierpinski fractal phononic crystals[J]. Modern Physics Letters B, 2015, 29(23): 1550134.

    [23] [23] GAO N S, WU J H, YU L. Research on bandgaps in two-dimensional phononic crystal with two resonators[J]. Ultrasonics, 2015, 56: 287-293.

    [24] [24] DUAN M Y, YU C L, XIN F X, et al. Tunable underwater acoustic metamaterials via quasi-Helmholtz resonance: from low-frequency to ultra-broadband[J]. Applied Physics Letters, 2021, 118(7): 071904.

    [25] [25] RAJENDRAN V, MNDEZ ECHENAGUCIA T I, PIACSEK A A. Design of efficient low-frequency sound absorbers using an array of Helmholtz Resonators[J]. The Journal of the Acoustical Society of America, 2020, 148(4): 2798-2799.

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    LIU Hong, ZHAO Jingbo, YAO Hong, HAN Donghai, ZHANG Xiaosheng, WANG Chen, ZHANG Guangjun. Bandgaps of a Helmholtz-Type Phononic Crystal with Adjustable Chamber[J]. Journal of Synthetic Crystals, 2023, 52(4): 590

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    Paper Information

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    Received: Dec. 12, 2022

    Accepted: --

    Published Online: Jun. 11, 2023

    The Author Email:

    DOI:

    CSTR:32186.14.

    Topics

    laser devices and laser physics
    Lasers and Laser Optics
    Laser physics
    laser manufacturing
    Instrumentation, Measurement and Metrology