Chinese Journal of Lasers, Volume. 49, Issue 1, 0101006(2022)
Progress in Chalcogenide Glass Photonic Crystal Fibers with Ultra-Large Mode Area
Figures & Tables(11)
![Summary of reported maximum incident CW laser damage threshold of ChG fibers[7-12]](/Images/icon/loading.gif){kind=icon}
Fig. 3. Fabrication flow of ULMA ChG PCF. (a)(c) Extruded chalcogenide glass rod and tubes for PCF fabrication; (d) preform composed by low-index rod and high-index tube using rod-in-tube method; (e) stacked ChG preform for ULMA PCF; (f) schematic of drawing all-solid ChG PCF
Fig. 4. Measured optical properties of host materials for ULMA ChG PCF and numerical simulations of single-mode ULMA ChG PCF. (a) Measured transmission and (b) refractive index curves of prepared Ge10As24S66 and Ge12As24Se64 glasses; (c) schematic of ULMA ChG PCF with two rings of low-index filling rods; calculated mode profiles of (d) LP01 and (e) LP11; calculated confinement losses (CL) of all-solid Ge-As-Se/Ge-As-S ULMA PCF with core diameter of 80 μm at the wavelength of 2 μm and 4 μm of the PCFs with (f) 2-ring structure and (g) 1-ring structure
Fig. 5. Measured guiding performances of fabricated single-mode ULMA ChG PCF. (a) Scanning electron microscope (SEM) photograph of single-mode ULMA ChG PCF; (b) near-field and (c) far-field mode profiles observed from ULMA ChG PCF output end at 4 μm; (d) measured loss spectra of unclad Ge12As24Se64 glass fiber in 29 μm and ULMA ChG PCF at 4 μm
Fig. 6. Origin of bending loss in PCF with ultra-low NA. (a) Straight fiber; (b) bent fiber
Fig. 7. Microstructure and numerical simulation of dual-moded ULMA ChG PCF. (a) Schematic of dual-moded ULMA ChG PCF; (b) SEM image of fabricated dual-moded ULMA ChG PCF;(c)calculated CLs of LP01 and LP11 modes of the fabricated fiber (Λ=90 μm, d1/Λ=0.40, and d2/Λ=0.55) in the range of 28 μm, in comparison with the PCF with uniform d/Λ=0.40 (d1=d2) and Λ=90 μm;(d)calculated Aeff of LP01 and LP11 modes of the fabricated fiber (Λ=90 μm, d1/Λ=0.40, and d2/Λ=0.55) in the range of 28 μm, in comparison with the PCF with uniform d/Λ=0.40 (d1=d2) and Λ=90 μm
Fig. 8. Measured bending loss and fitting with exponential decay function of dual-moded ULMA ChG PCF with bending radius under different diameters of the incident 2-μm laser spot. (a) ~75 μm; (b) ~100 μm
Fig. 9. Measured optical homogeneity of Ge-As-Se chalcogenide glass with 100-mm aperture
Table 1. Reported maximum resisted mid-IR power of ChG fibers
View tableTable 1. Reported maximum resisted mid-IR power of ChG fibers
Laser wavelength /μm Fiber host Core diameter /μm Maximum resisted power /W Fiber type Ref. 2 As2S3 12 12 Few-moded fiber excited by LP01 mode [ 10 ]5.4 As2S3 1000 460 Multimode fiber [ 7 ]10.6 Ge-As-Se-Te 400 6.16 Multimode fiber [ 12 ]
Table 2. Damage threshold of various glass fibers, including silica, fluoride, fluorotellurite, and ChG fibers under CW laser irradiation
View tableTable 2. Damage threshold of various glass fibers, including silica, fluoride, fluorotellurite, and ChG fibers under CW laser irradiation
Fiber host material Laser damage threshold /(GW·cm-2) Ref. Silica (SiO2) ~0.8 [ 28 ]Fluorotellurite (TeO2-BaF2-Y2O3) ~0.07 [ 34 ]Fluoride(ZrF4-based) ~0.02 [ 31 ]Chalcogenide (Ge-As-S) 0.01-0.02 [ 11 ]
Tools
Get Citation
Copy Citation Text
Xian Feng, Zhiyong Yang, Jindan Shi. Progress in Chalcogenide Glass Photonic Crystal Fibers with Ultra-Large Mode Area[J]. Chinese Journal of Lasers, 2022, 49(1): 0101006
Paper Information
Category: laser devices and laser physics
Received: Sep. 1, 2021
Accepted: Oct. 18, 2021
Published Online: Dec. 13, 2021
The Author Email: Feng Xian (xianfeng@jsnu.edu.cn), Yang Zhiyong (zhiyongyang@jsnu.edu.cn), Shi Jindan (shi.jindan@jsnu.edu.cn)
© Copyright 2018-2021 | Chinese Laser Press.
All Rights Reserved 沪ICP备15018463号-20