空芯光子晶体光纤导波模式特性分析

J4 ›› 2010, Vol. 27 ›› Issue (2): 252-256.

• 纤维与波导光学 • 上一篇

空芯光子晶体光纤导波模式特性分析

刘二明孙青尚亮常建华毛庆和

中国科学院安徽光学精密机械研究所，安徽省光子器件与材料重点实验室，安徽合肥 230031

出版日期:2010-03-28 发布日期:2010-03-05
通讯作者: 毛庆和（1963-），研究员，博士生导师，主要从事纤维光学与激光技术方面的研究。 E-mail:mqinghe@aiofm.ac.cn
作者简介:刘二明（1985-），硕士，研究方向为光子晶体光纤数值模拟。

Analysis of guided-mode properties for hollow-core photonic crystal fibers

LIU Er-Ming, SUN Qing, SHANG Liang, CHANG Jian-Hua, MAO Qing-He

Anhui Provincial Key Lab of Photonics Devices and Materials, Anhui Institute of Optics and Fine Mechanics, Chinese Academy of Sciences, Hefei 230031, China

Published:2010-03-28 Online:2010-03-05

摘要/Abstract

摘要：

采用平面波展开法研究了空芯光子晶体光纤(HC-PCF)的导波模式特性。结果表明，在包层带隙范围内，当导波模的纵向相位传播常数满足一定条件时，才能在HC-PCF纤芯中形成稳定的基模传输；并且，纤芯基模的模场分布与光波长有关，当光波长位于纤芯基模传输曲线中央时，光波能量被很好地约束在纤芯中，而当光波长位于纤芯基模传输曲线的上下边沿时，光波能量将向包层中漏泄。

关键词: 纤维与导波光学, 空芯光子晶体光纤, 平面波展开法, 光子禁带, 导波模式

Abstract:

The guided-mode properties of hollow-core photonic crystal fibers (HC-PCFs) were studied with the plane-wave expansion method (PWE). The simulation results show that, for a given wavelength in the photonic band-gap of the cladding structure, stable fundamental core mode may be obtained only with specific vertical phase propagating constants. Moreover, the mode field distributions of fundamental core modes depend on the wavelength. When the wavelength is right at the center of the fundamental core mode transmitting curve, the mode field may be confined in the air-core perfectly; when the wavelength is near the edges of the fundamental core mode transmitting curve, the energy of guided-wave core modes may leak into the cladding of HC-PCF.

Key words: fiber and waveguide optics, hollow-core photonic crystal fiber, plane-wave expansion method, photonic band-gap, guided-modes

刘二明孙青尚亮常建华毛庆和. 空芯光子晶体光纤导波模式特性分析[J]. J4, 2010, 27(2): 252-256.

LIU Er-Ming, SUN Qing, SHANG Liang, CHANG Jian-Hua, MAO Qing-He. Analysis of guided-mode properties for hollow-core photonic crystal fibers[J]. J4, 2010, 27(2): 252-256.

参考文献

[1] Russell P S J, Photonic-crystal fibers

[J]. IEEE J. of Lightwave Technol., 2006, 24(12): 4729-4749.

[2] Sun Qing, Mao Qinghe, Ming Hai. Recent advances in hollow-core photonic crystal fibers: an up date view

[J].Chinese Journal of Quantum Electronics(量子电子学报), 2007, 23(4): 433-440(in Chinese).

[3] Shephard J D, Roberts P J, Jones J D C, Knight J C and Hand D P, Measuring beam quality of hollow core photonic crystal fibers

[J]. IEEE J. of Lightwave Technol., 2006, 24(10): 3761-3769.

[4] Barkou S E, Broeng J and Bjarklev A. Silica-air photonic crystal fiber design that permits wave guiding by a true photonic bandgap effect

[J]. Opt. Lett., 1999, 24(1): 46-48.

[5] Broeng J, Barkou S E, Sondergaard, T and Bjarklev A, Analysis of air-guiding photonic bandgap fibers

[J]. Opt. Lett., 2000, 25(2): 96-98.

[6] Li Shu-Guang, Liu Xiao-Dong and Hou Lan-Tian, The study of waveguide mode and dispersion property in photonic crystal fibres

[J]. Acta Physica Sinica(物理学报), 2003, 52(11): 2811-2817(in Chinese).

[7] Wang Zhi, Ren Guobin, Lou Shuqin, Liang Weijun and Jian Shuisheng, The mode characteristics of the photonic crystal fibers

[J]. Acta Optica Sinica(光学学报), 2004, 24(3): 324-329(in Chinese).

[8] Qiu M, Analysis of guided modes in photonic crystal fibers using the finite-difference time-domain method

[J]. Microwave and Optical Technology Letters, 2001, 30(5): 327-330.

[9] Shen G Q, Chen Y C and Mittra R, A nonuniform FDTD technique for efficient analysis of propagation characteristics of optical-fiber waveguides. IEEE Transactions on Microwave Theory and Techniques

[J].1999, 47(3):345-349.

[10] Joannopoulos J D, Villeneuve P R, and Fan S, Photonic crystal: putting a new twist on light

[J]. Nature, 1997 386: 143-149

[11] Feng Xiao-Ping, Arakawa Y, Off-plane angle dependence of photonic bandgap in a two-dimensional photonic crystal

[J]. IEEE. J. of Quantum Electron., 1996, 32(3):535-541.

[12] Johnson S G and Joannopoulos J D, Block-iterative frequency-domain methods for Maxwell's equations in a planewave basis

[J], Opt. Express, 2001, 8(3): 173-190.

[13] Dangui V, Digonnet M J F and Kino G S, A fast and accurate numerical tool to model the modal properties of photonic-bandgap fibers

[J], Opt. Express, 2006, 14(7): 2979-2993.

[14] West J A, Smith C M, Borrelli N F, Allan D C and Koch K W, Surface modes in air-core photonic band-gap fibers

[J]. Opt. Express, 2004, 12(8): 1485-1496.

[15] Kim H K, Digonnet M J F, Kino G S, J. W. Shin and S. H. Fan, Simulations of the effect of the core ring on surface and air-core modes in photonic bandgap fibers

[J]. Opt. Express, 2004, 12(15): 3436-3442.

空芯光子晶体光纤导波模式特性分析

Analysis of guided-mode properties for hollow-core photonic crystal fibers

可视化

摘要/Abstract

引用本文

使用本文

参考文献

相关文章 8

编辑推荐

Metrics

本文评价

[1]	叶铮, 武校刚∗, 马佳勇, 潘文亮, 唐秀陆. 一维光子晶体的湿敏禁带特性研究[J]. 量子电子学报, 2022, 39(3): 452-458.
[2]	魏常1, 王玉莲2, 时金辉3, 张国生4 . 非膜片式全光纤结构音频传感器[J]. 量子电子学报, 2019, 36(2): 243-247.
[3]	李贺飞, 徐翠萍, 田春雨，宫奎，冯飞，徐峰，甄胜来，俞本立. 一种基于套嵌光纤光栅的高灵敏度光纤电流传感器[J]. J4, 2016, 33(5): 598-603.
[4]	刘雯，孙晓红，刘薇. 光子晶体旋转角度对带隙特性的影响[J]. J4, 2014, 31(3): 329-334.
[5]	高净节孙晓红. 十重准晶光子晶体结构带隙特性的研究[J]. J4, 2013, 30(2): 207-212.
[6]	濮荣强余红英沈林放. 二维介质柱正方复合周期结构光子晶体的禁带研究[J]. J4, 2012, 29(6): 735-740.
[7]	陈士芹. Ⅲ-Ⅴ族半导体材料组成光子晶体能态密度特性[J]. J4, 2012, 29(4): 491-494.
[8]	张旋廖清华于天宝刘念华. 一种新型多模干涉型光子晶体波分解复用器[J]. J4, 2011, 28(6): 753-758.