Numerical simulation and experimental analysis of photonic band gap in hollow-core photonic crystal fibres

Yuan JH; Hou LT; Zhou GY; Wei DB; Chen C; Wang QY; Hu ML; Liu BW

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Numerical simulation and experimental analysis of photonic band gap in hollow-core photonic crystal fibres

机译：中空光子晶体光纤中光子带隙的数值模拟和实验分析

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Based on the full-vector plane-wave method (FVPWM), a hollow-core photonic crystal fibre (HC-PCF) fabricated by using the improved stack-and-draw technique is simulated. Under given propagation constants beta, several effective photonic band gaps with different sizes emerge within the visible wavelength range from 575 to 720 nm. The fundamental mode and second-order mode lying in a part of PBGs are investigated. In the transmission spectrum tested, the positions of PBGs are discovered to be shifting to shorter wavelengths. The main reason is the existence of interstitial holes at nodes in the cladding region. In the later experiment, green light is observed propagating in the air-core region, and the result is more consistent with our theoretical simulation.

机译：基于全矢量平面波方法（FVPWM），对采用改进的叠拔技术制造的空心光子晶体光纤（HC-PCF）进行了仿真。在给定的传播常数β下，在575至720 nm的可见波长范围内出现了几个大小不同的有效光子带隙。研究了部分PBG中的基本模式和二阶模式。在测试的透射光谱中，发现PBG的位置正在向较短的波长移动。主要原因是在包层区域的节点处存在间隙孔。在后面的实验中，观察到绿光在空心区域中传播，其结果与我们的理论模拟更加一致。

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来源
《Chinese physics letters》 |2008年第5期|共4页
作者
Yuan JH; Hou LT; Zhou GY; Wei DB; Chen C; Wang QY; Hu ML; Liu BW;
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正文语种 eng
中图分类物理学;
关键词
SUPERCONTINUUM GENERATION; AIR; PULSES; NM;

机译：超连续发电;空气;脉冲;NM;

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1. Numerical simulation and experimental analysis of photonic band gap in hollow-core photonic crystal fibres [J] . Yuan JH, Hou LT, Zhou GY, Chinese physics letters . 2008,第5期

机译：中空光子晶体光纤中光子带隙的数值模拟和实验分析
2. Numerical Simulation and Experimental Analysis of Photonic Band Gap in Hollow-Core Photonic Crystal Fibres [J] . YUAN Jin-Hui, HOU Lan-Tian, ZHOU Gui-Yao, 中国物理快报：英文版 . 2008,第005期

机译：中空光子晶体光纤中光子带隙的数值模拟与实验分析
3. Filament fusion of hollow-core photonic crystal fiber and single mode fiber: numerical simulation and experimental analysis [J] . Wang Chen-ge, Wang Lei, She Xuan, Laser Physics: An International Journal devoted to Theoretical and Experimental Laser Research and Application . 2019,第5期

机译：空心光子光子晶体纤维和单模光纤的长丝融合：数值模拟和实验分析
4. Double photonic band gap hollow-core photonic crystal fiber [C] . Fetah Benabid, rnFrancis Couny, rnPhilip S. Light Photonic and phononic crystal materials and devices X . 2010

机译：双光子带隙中空光子晶体光纤
5. Computation of photonic band structure and transmission spectra of two-dimensional photonic bandgap crystals. [D] . Qiu, Yang. 1998

机译：二维光子带隙晶体的光子能带结构和透射光谱的计算。
6. Multi-Line Fit Model for the Detection of Methane at ν2 + 2ν3 Band using Hollow-Core Photonic Bandgap Fibres [O] . Ana M. Cubillas, Jose M. Lazaro, Olga M. Conde, 2009

机译：中空光子带隙光纤在ν2+2ν3波段检测甲烷的多线拟合模型
7. Numerical computation of band gaps in photonic crystal fibres [O] . Norton Richard 2008

机译：光子晶体光纤中带隙的数值计算

Numerical simulation and experimental analysis of photonic band gap in hollow-core photonic crystal fibres

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