Dispersion design of all-solid photonic bandgap fiber

Fang Q; Wang Z; Jin L; Liu JG; Yue Y; Liu Y; Kai GY; Yuan SZ; Dong XY

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Dispersion design of all-solid photonic bandgap fiber

机译：全固态光子带隙光纤的色散设计

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We propose a novel design for all-solid photonic bandgap fiber (AS-PBGF) by introducing defect rods with larger diameters into fiber cladding. By means of the plane-wave expansion method and the full-vector finite-element method, we study the effect of introducing such defect rods and numerically investigate dispersion characteristics of proposed AS-PBGF. Simulation results demonstrate that large wave guide group-velocity dispersion (GVD) (both normal and anomalous) is induced within bandgap rather than near the edge of bandgap as conventional photonics bandgap fiber does, which guarantees that large dispersion and low confinement loss could be simultaneously achieved. We also find that there are two essential factors affecting the slope of wave-guide GVD, which determines the third-order dispersion: number of defect rods and the ring where defect rods are introduced. (c) 2007 Optical Society of America

机译：我们通过将直径较大的缺陷棒引入光纤包层中，为全固态光子带隙光纤（AS-PBGF）提出了一种新颖的设计。通过平面波扩展法和全矢量有限元法，研究了引入这种缺陷棒的效果，并数值研究了所提出的AS-PBGF的色散特性。仿真结果表明，在带隙内而不是在带隙边缘附近会产生大的波导群速度色散（正常和异常），而不是像常规光子带隙光纤那样，这确保了大色散和低限位损失可以同时发生实现。我们还发现，影响波导GVD斜率的两个基本因素决定了三阶色散：缺陷棒的数量和引入缺陷棒的环。（c）2007年美国眼镜学会

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《Journal of the Optical Society of America, B. Optical Physics》 |2007年第11期|共7页
作者
Fang Q; Wang Z; Jin L; Liu JG; Yue Y; Liu Y; Kai GY; Yuan SZ; Dong XY;
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正文语种 eng
中图分类光学;
关键词
CRYSTAL FIBERS; GAP FIBERS; NM; COMPENSATION; IMPACT; LASER;

机译：晶体纤维;间隙纤维;NM;补偿;冲击;激光;

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专利

1. Dispersion design of all-solid photonic bandgap fiber [J] . Fang Q, Wang Z, Jin L, Journal of the Optical Society of America, B. Optical Physics . 2007,第11期

机译：全固态光子带隙光纤的色散设计
2. Proposal for All-Solid Photonic Bandgap Fiber With Improved Dispersion Characteristics [J] . Fang Q., Wang Z., Kai G., IEEE Photonics Technology Letters . 2007,第16期

机译：具有改善色散特性的全固态光子带隙光纤的提案
3. Design Optimization of Large-Mode-Area All-Solid Photonic Bandgap Fibers for High-Power Laser Applications [J] . Saitoh S., Saitoh K., Kashiwagi M., Journal of Lightwave Technology . 2014,第3期

机译：大功率面积全固态光子带隙光纤在大功率激光应用中的设计优化
4. Dual-concentric-core all-solid photonic bandgap fiber with large dispersion [C] . Qiang Fang, Zhi Wang, Long Jin, Conference on Passive Components and Fiber-based Devices; 20071102-05; Wuhan(CN) . 2007

机译：具有较大色散的双同心芯全固态光子带隙光纤
5. Photonic bandgap fibers for transverse strain sensing. [D] . Van Vickle, Patrick Stephen. 2008

机译：用于横向应变传感的光子带隙光纤。
6. Photonic Bandgap Propagation in All-Solid Chalcogenide Microstructured Optical Fibers [O] . Celine Caillaud, Gilles Renversez, Laurent Brilland, 2014

机译：全固态硫族化物微结构光纤中的光子带隙传播。
7. All-PM monolithic fs Yb-fiber laser, dispersion-managed with all-solid photonic bandgap fiber [O] . Liu Xiaomin, Lægsgaard Jesper, Turchinovich Dmitry 2009

机译：全pm单片fs Yb光纤激光器，采用全固态光子带隙光纤进行色散管理
8. Extending Mode Areas of Single-mode All-solid Photonic Bandgap Fibers. [R] . Gu, G., Kong, F., Hawkins, T. W., 2015

机译：扩展单模全固态光子带隙光纤的模式区域。

Dispersion design of all-solid photonic bandgap fiber

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