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光子晶体齿状波导的滤波特性研究

刘云凤 刘彬 陈佳 何兴道 李淑静

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文章导航 > 激光技术  > 2016 >  40(2): 237-240
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光子晶体齿状波导的滤波特性研究

  • 1.

    南昌航空大学江西省光电检测技术工程实验室, 南昌 330063;

  • 2.

    南昌工学院机械工程学院, 南昌 330000

    • 作者简介: 刘云凤(1992-),女,硕士研究生,现主要从事光子晶体理论与应用的研究。.
    通讯作者: 何兴道, 154440991@qq.com
  • 基金项目:

    国家自然科学基金资助项目(61205119)

  • 中图分类号: TN256

Study on filtering characteristics based on tooth-shaped photonic crystal waveguide

  • 1.

    Jiangxi Engineering Laboratory for Optoelectronics Testing Technology, Nanchang Aeronautical University, Nanchang 330063, China;

  • 2.

    School of Mechanical Engineering, Nanchang Institute of Science & Technology, Nanchang 330000, China

    • Corresponding author: HE Xingdao, 154440991@qq.com ;

  • CLC number: TN256

  • 摘要: 为了设计基于光子晶体波导的高性能滤波器件,在2维正方格子光子晶体波导结构中引入一系列齿状缺陷,采用有限元法对齿状光子晶体波导的传输特性进行了数值仿真和理论分析。结果表明,对于单个齿状缺陷,缺陷产生的共振频率使得在光子晶体波导通频域带出现带隙结构,可以实现良好的窄带滤波,并且通过改变齿状缺陷深度可以有效地控制缺陷的共振频率;引入多个齿状缺陷,缺陷之间会经过耦合作用形成一系列缺陷态,使得在光子晶体波导导通频域中出现宽带的带隙结构,可以实现宽带滤波。该光子晶体波导滤波器对窄/宽带滤波可根据波导结构中引入的齿状缺陷进行简单灵活调节。此研究在设计基于光子晶体波导的光子滤波器件方面具有潜在的应用价值。
    Abstract: In order to design high performance filters based on photonic crystal waveguide, new band-stop filter was proposed by introducing a series of tooth-shaped defects into 2-D photonic crystal waveguide. Transmission characteristics of tooth-shaped photonic crystal waveguide were studied by finite element method. The results show that, for single tooth-shaped defect, resonance frequency generated by defect leads to a band-stop structure and good narrowband filter is achieved. Resonance frequency can be modulated by changing the depth of defect. For multiple tooth-shaped defects, due to the coupling effect, a series of defects form a wide band stop of photonic crystal waveguide with relatively wider bandwidth. Photonic crystal waveguide filters can be simple and fiexible adjustment by introducing tooth-shaped defects to achieve narrow/broadband filters. The study has potential value in the design of photonic filter devices based on photonic crystal waveguides.
  • [1]

    YABLONVITCH E. Inhibited spontaneous emission in solid-state physics an electronics[J]. Physical Review Letters,1987, 58(20):2059-2062.
    [2]

    JONH S. Strong localization of photons in certain disordered dielectric superlattices[J]. Physical Review Letters, 1987, 58(23):2486-2489.
    [3]

    DAVID A, BENISTY H, WEISBUCH C. Photonic crystal light-emitting sources[J].Reports on Progress in Physics,2012,75(12):126501-126538.
    [4]

    XU Q, PENG C Y. The properties of two-dimensional photonic crystals bandgap structure with rhombus lattice[J]. Optik-International Journal for Light and Electron Optics, 2014, 125(1):104-106.
    [5]

    WANG Zh Q, ZHAO Ch L, JIN Sh Zh. Design of a bending-insensitive single-mode photonic crystal fiber[J]. Optical Fiber Technology, 2013, 19(3):213-218.
    [6]

    YAJIMA T, YAMAMOTO J, LSHII F, et al. Low-loss photonic crystal fiber fabricated by a slurry casting method[J]. Optics Express, 2013, 21(25):30500-30506.
    [7]

    LEBBAL M R, BOUMAZA T, BOUCHEMAT M. Structural study of the single-mode photonic crystal fiber[J]. Optik-International Journal for Light and Electron Optics, 2013, 124(20):4610-4613.
    [8]

    ZHANG G L, XING F F, YAN P G, et al. Double cladding seven-core photonic crystal fiber[J]. Optics and Photonics Journal, 2013, 3(2):47-49.
    [9]

    HASAN Md I, HABIB M S, HABIB M S, et al. Design of hybrid photonic crystal fiber:polarization and dispersion properties[J]. Photonics and Nanostructures-Fundamentals and Applications, 2014, 12(2):205-211.
    [10]

    SHEN X X, REN Y Z, DONG G Y, et al. Optimization design of holographic photonic crystal for improved light extraction efficiency of GAN LED[J]. Superlattices and Microstructures, 2013, 64:303-310.
    [11]

    CHEN Y Y, SUN B, MA T H, et al. Thermal management for high-power photonic crystal light emitting diodes[J]. Microelectronics Reliability, 2014, 54(1):124-130.
    [12]

    MAHMOUD M Y, BASSOU G, METEHRI F. Channel drop filter using photonic crystal ring resonators for CWDM communication systems[J]. Optik-International Journal for Light and Electron Optics, 2014, 125(17):4718-4721.
    [13]

    LI L, LIU G Q. Photonic crystal ring resonator channel drop filter[J]. Optik-International Journal for Light and Electron Optics, 2013, 124(17):2966-2968.
    [14]

    REN K, REN X B. Y-shaped beam splitter by graded structure design in a photonic crystal[J]. Chinese Science Bulletin, 2012, 57(11):1241-1245.
    [15]

    ZHANG L L, LI Q, WANG Q. 1-to-N beam splitter based on photonic crystal branched waveguide structure[J]. Optics and Laser Technology,2011,43(7):1325-1330.
    [16]

    JANRAO N, JANYANI V. Ultra compact slow light photonic crystal directional coupler design with elliptical rods[J]. Optik-International Journal for Light and Electron Optics, 2013, 124(17):3120-3124.
    [17]

    ZHANG P Y. Novel composite beam splitter with directional coupler and Y-junction using photonic crystal[J]. Optik-International Journal for Light and Electron Optics, 2013, 124(18):3384-3386.
    [18]

    HE Y, WANG T, YAN W, et al. All-optical switching based on the electromagnetically induced transparency effect of an active photonic crystal microcavity[J]. Journal of Modern Optics, 2014, 61(5):403-408.
    [19]

    CHEN Y, LIU T, LU B, et al. Design and numerical studies of composite defect photonic crystal optical filter[J]. Optical Technique, 2014,40(2):172-175(in Chinese).
    [20]

    LI W, WANG Ch S, WANG B Y, et al. Design and research the resonance of the photonic crystal coupled filter[J]. Laser Journal, 2013, 34(1):17-18(in Chinese).
    [21]

    ZHOU P, YAN M B, WANG H L. Research of the transmission spectra of photonic crystal waveguide with layered composite medium cylinder[J].Laser Technology, 2009, 33(2):195-197(in Chinese).
    [22]

    SAJEEV J. Localization of light[J]. Physics Today, 1991, 44(5):32-40.
    [23]

    YABLONOVITCH E, GMITTER T J, MEADE R D, et al. Donor and acceptor modes in photonic band structure[J]. Physical Review Letters, 1991, 67(24):3380-3383.
    [24]

    LIU N H. Defect modes of stratified dielectric media[J]. Physical Review, 1997, B55(7):4097-4100.
    [25]

    YANG G G. Advance physcial optics[M]. Hefei:University of Science and Technology of China Press, 1991:28-32(in Chinese).
    [26]

    ZHANG L Ch, LIANG B M, ZHUANG S L. Coupling of two parallel photonic crystal waveguide and application.Opto-Electronic Engineering, 2011,38(7):25-30(in Chinese).
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  • 收稿日期:  2015-01-13
  • 录用日期:  2015-03-10
  • 刊出日期:  2016-03-25

光子晶体齿状波导的滤波特性研究

    通讯作者: 何兴道, 154440991@qq.com
    作者简介: 刘云凤(1992-),女,硕士研究生,现主要从事光子晶体理论与应用的研究。
  • 1. 南昌航空大学江西省光电检测技术工程实验室, 南昌 330063;
  • 2. 南昌工学院机械工程学院, 南昌 330000
  • 收稿日期: 2015-01-13
  • 录用日期: 2015-03-10
  • 网络出版日期: 2016-03-25
基金项目:  国家自然科学基金资助项目(61205119)

摘要: 为了设计基于光子晶体波导的高性能滤波器件,在2维正方格子光子晶体波导结构中引入一系列齿状缺陷,采用有限元法对齿状光子晶体波导的传输特性进行了数值仿真和理论分析。结果表明,对于单个齿状缺陷,缺陷产生的共振频率使得在光子晶体波导通频域带出现带隙结构,可以实现良好的窄带滤波,并且通过改变齿状缺陷深度可以有效地控制缺陷的共振频率;引入多个齿状缺陷,缺陷之间会经过耦合作用形成一系列缺陷态,使得在光子晶体波导导通频域中出现宽带的带隙结构,可以实现宽带滤波。该光子晶体波导滤波器对窄/宽带滤波可根据波导结构中引入的齿状缺陷进行简单灵活调节。此研究在设计基于光子晶体波导的光子滤波器件方面具有潜在的应用价值。

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