Research Progress of Chalcogenide Glass Photonic Crystal Fibers

Shixun, 戴世勋 Dai; Xingyan, 於杏燕 Yu; Wei, 张巍 Zhang; Changgui, 林常规 Lin; Baoan, 宋宝安 Song; Xunsi, 王训四 Wang; Yongxing, 刘永兴 Liu; Tiefeng, 徐铁峰 Xu; Qiuhua, 聂秋华 Nie

doi:10.3788/lop48.090602

Cited by 3 publications

(2 citation statements)

References 0 publications

Supporting

Mentioning

Contrasting

Unclassified

Order By: Relevance

“…璃拉制 [41] ， CO2 激光器加热拉制 [42] ，电极加热拉制 [43] ，其中，两步拉伸法是第一种被报道的拉制方法，拉制简单便捷，拉制的微纳光纤最小直径为 50 nm；自调节拉伸法在目前的方法中可获得最小直径的微纳光纤，最小直径为 20 nm；由掺杂的块状玻璃棒拉制可获得各种有源微纳光纤，最小直径为 50 nm [41] ； CO2 激光器加热拉制可以克服使用火焰加热带来的气流影响，拉制的光纤直径为 3000~4000 nm [42] ；电极加热拉制，在目前的方法中可以拉制出长度最长的微纳光纤，最小直径为 900 nm，这些方法各有优点，所拉制的微纳光纤在几何参 [44] 。目前已报道的产生超连续谱的光纤主要有以下几种：色散位移型光纤、色散平坦型光纤、色散渐减型光纤和色散平坦渐减型光纤。对具有不同色散特性光纤产生超连续谱进行了详细的理论计算和分析，结果表明：在反常色散区和零色散区，不能产生平坦、宽带的超连续谱，而在正常色散区可以产生更宽更平坦的超连续谱 [45] 。硫系玻璃具有极高的折射率(2.0~3.5)和非线性折射率 n2 (n2=2~20×10 -18 m 2 /W) [5][6]…”

Section: -unclassified

Research Progress of Micro/nano-Optical Device Based on Chalcogenide Glass

Sheqin¹,

Chaoran²,

Yuehao³

et al. 2014

激光与光电子学进展

Self Cite

View full text Add to dashboard Cite

Micro/nano-optical devices are some optical devices which have micro/nano-scale size， and they have some advantages，such as small volume，high reliability，high coupling efficiency，light weight，flexible design and easy integration. As a novel substrate material of micro/nano-optical device，chalcogenide glass possess some unique advantages， such as large infrared transmission window， ultrahigh nonlinear coefficient， smaller two photon absorption coefficient， ultrashort nonlinear response time and tailorable compositions. In recent years，chalcogenide glass micro/nano-optical devices have attracted many attentions. The research progress of chalcogenide glass micro/nano-device is reviewed in terms of chalcogenide glass micro/nano-fiber， microsphere，photonic crystal and microring.Their potential applications and development prospects are also discussed.

show abstract

Section: -unclassified

Research Progress of Micro/nano-Optical Device Based on Chalcogenide Glass

Sheqin¹,

Chaoran²,

Yuehao³

et al. 2014

激光与光电子学进展

Self Cite

View full text Add to dashboard Cite

show abstract

“…Chalcogenide optical fibers are non-oxide optical fibers comprising sulfur, selenium, tellurium, and other metal elements (germanium, arsenic, antimony, etc). They are characterized by superior performance including a high refractive index (2.0-3.5), low phonon energy (less than 350 cm −1 ), excellent mid-far infrared (up to 20 μm) transmission, maximized nonlinear refractive index coefficient [n 2 = (1.5-20) × 10 −18 m 2 W −1 , 100-1000 times that of quartz glass], and adjustable components [14]. Chalcogenide optical fibers are the only highly nonlinear fibers that can achieve an infrared-band SC spectrum spanning 2-16 μm.…”

Section: Introductionmentioning

confidence: 99%

Broadband flat supercontinuum generated by chalcogenide double-clad step-index fiber with special dispersion

Liu,

Li,

Liao

et al. 2024

Phys. Scr.

View full text Add to dashboard Cite

To achave a broader supercontinuum in the mid-infrared band, a chalcogenide double-clad step-index fiber is proposed. Comprising As2Se3, AsSe2, and As2S5 glass, this fiber effectively confines light within the core, minimizing fiber dispersion fluctuations. By iteratively adjusting the dispersion curve of the fiber, enhancement of the supercontinuum spectrum generation is possible. Spectral broadening primarily results from four-wave mixing and self-phase modulation. Raman scattering within the pulse generates unstable higher-order solitons, which, upon breakup, contribute to spectrum broadening. This study explores the effects of pulse laser parameters and fiber length on supercontinuum generation, obtains regular cognition and offers theoretical analyses of the results. Through optimization of parameters, a mid-infrared supercontinuum with an 11 μm width is achieved. These findings underscore the potential of chalcogenide double-clad step-index fiber for generating a mid-infrared supercontinuum light source. The designed fiber structure should be helpful in supercontinuum sources, bio-molecule sensing, and spectroscopy.

show abstract