Chinese Journal of Lasers, Volume. 48, Issue 4, 0401008(2021)
Progress and Prospects of Fiber Gas Laser Sources (Ⅰ) :Based on Stimulated Raman Scattering
Figures & Tables(10)
Fig. 1. Energy level transition diagram of hydrogen molecule during stimulated Raman scattering
Fig. 5. Experiment of vibrational stimulated Raman scattering of hydrogen in HCF[7]. (a)System structure;(b)output spectra
Fig. 6. Experimental structures of rotational stimulated Raman scattering of hydrogen in HCF[26]. (a) Single-pass structure; (b) resonant cavity structure
Table 1. Raman frequency shifts of common gases and their first-order Stokes wavelengths
View tableTable 1. Raman frequency shifts of common gases and their first-order Stokes wavelengths
Gain gas Raman frequency shift / cm-1 Stokes wavelength pumpd at 1064nm /nm Stokes wavelength pumpd at 1550nm /nm H2 4155 1907 4354 587 1135 1705 354 1106 1640 D2 2987 1560 2886 415 1113 1657 297 1098 1625 179 1084 1594 CH4 2917 1543 2829 C2H6 2954 1552 2859 CO2 1389 1249 1975 CF4 908 1178 1804 SF6 775 1160 1762
Table 2. Progress of fiber gas Raman laser sources
View tableTable 2. Progress of fiber gas Raman laser sources
Reference Pump wavelength Raman wavelength Gas Raman power (fiber length) Conversion efficiency [7] 532nm 683nm H2 30%(power conversion efficiency) [26] 1064nm 1135nm H2 50%(quantum efficiency) [27] 1064nm 1135nm H2 92%(quantum efficiency) [30] 1064nm 1135nm H2 55W(30m) >70%(power conversion efficiency) [31] 1064nm 1907nm H2 10mW(6.5m) 48%(quantum efficiency) [32] 1064nm 1907nm H2 330mW(2.25m) 60%(quantum efficiency) [33] 1064nm 1907nm H2 40%(quantum efficiency) [34] 1064nm 1908nm H2 74.2mW(1.4m) 73.5%(quantum efficiency) [35] 1064nm 1907nm H2 55mW(1.4m) 54%(quantum efficiency) [36] 1064nm 1908nm H2 570mW(2m) 51.1%(quantum efficiency) [37] 1μm 1.8μm H2 9.3W(1m) 41%(power conversion efficiency) [38] 1550nm 1705nm H2 0.5W(3m) 32%(power conversion efficiency) [39] 1535--1565nm 1687--1723nm H2 0.8W(20m) 60%(power conversion efficiency) [40] 1558nm 4.4μm H2 30mW(15m) 15%(quantum efficiency) [41] 1558nm 4.42μm H2 250mW(3.5m) 36%(quantum efficiency) [42-43] 1558nm 4.42μm H2 1.4W(3.2m) 53%(quantum efficiency) [46] 1558nm 2.9μm H2/D2 0.25kW(11m) 10%(quantum efficiency) [47] 1064nm 1561nm D2 27mW(2.2m) 30%(power conversion efficiency) [47] 1561nm 2865nm CH4 8.5mW(2m) 42%(power conversion efficiency) [48] 1535--1565nm 1640--1674nm D2 0.8W(20m) 60%(power conversion efficiency) [50] 1064nm 1553nm C2H6 24.6mW(6m) 38%(power conversion efficiency) [52] 1064nm 1544nm CH4 43mW(2m) 96.3%(quantum efficiency) [53] 1064nm 1544nm CH4 0.83W(3.2m) 45%(power conversion efficiency) [54] 1064nm 2809nm CH4 13.8mW 65%(quantum efficiency) [55] 1064nm 2812nm CH4 113mW 40%(quantum efficiency) [57] 1540--1560nm 2796--2863nm CH4 34mW(14.2m) [58] 1064nm 1248nm CO2 5mW(3m) 37%(power conversion efficiency) [59] 1030nm 1119nm SF6 55.7%(power conversion efficiency) [59] 1030nm 1136nm CF4 45.4%(power conversion efficiency)
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Zefeng Wang, Wei Huang, Zhixian Li, Zhiyue Zhou, Yulong Cui, Hao Li. Progress and Prospects of Fiber Gas Laser Sources (Ⅰ) :Based on Stimulated Raman Scattering[J]. Chinese Journal of Lasers, 2021, 48(4): 0401008
Paper Information
Special Issue: SPECIAL ISSUE FOR "NATIONAL UNIVERSITY OF DEFENSE TECHNOLOGY"
Received: Apr. 22, 2020
Accepted: Jun. 11, 2020
Published Online: Jan. 15, 2021
The Author Email: Wang Zefeng (zefengwang_nudt@163.com)
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