高功率光纤激光器抽运耦合技术的现状和发展 下载: 1079次
李杰, 陈子伦, 周航, 郭少锋, 许晓军. 高功率光纤激光器抽运耦合技术的现状和发展[J]. 激光与光电子学进展, 2012, 49(2): 020003.
Li Jie, Chen Zilun, Zhou Hang, Guo Shaofeng, Xu Xiaojun. Status and Development of Pumping Technology for High Power Fiber Lasers[J]. Laser & Optoelectronics Progress, 2012, 49(2): 020003.
[1] 姚建铨, 任广军, 张强 等. 掺镱双包层光纤激光器及其泵浦耦合技术[J]. 激光杂志, 2006, 27(5): 1~4
[2] 楼祺洪, 周军, 朱健强 等. 高功率光纤激光器研究进展[J]. 红外与激光工程, 2006, 35(2): 135~138
[3] 楼祺洪, 周军, 张海波 等. 大芯径光纤激光器的新进展[J]. 中国激光, 2010, 37(9): 2235~2241
[4] 光纤激光时代来临——光纤激光器第三代激光器的代表[OL]. http://www.laserfocusworld.com.cn/DeMT.asp id=152, 2010009-09
[5] E. Snitzer. Optical maser action of Nd3+ in a barium crown glass[J]. Phys. Rev. Lett., 1961, 7(12): 444~446
[6] R. J. Mears, L. Reekie, I. M. Jauncey et al.. Low-noise erbium-doped fibre amplifier operating at 1.54 μm[J]. Electron. Lett., 1987, 23(19): 1026~1028
[7] E. Desurvire, J. R. Simpson, P. C. Becker. High-gain erbium-doped traveling-wave fiber amplifier[J]. Opt. Lett., 1987, 12(11): 888~890
[8] E. Snitzer, H. Po, F. Hakimi et al.. Double-clad, offset core Nd fiber laser[C]. OSA Technical Digest of Optical Fiber Sensors, 1988, 2: PD5
[9] H. M. Pask, J. L. Archambault, D. C. Hanna et al.. Operation of cladding-pumped Yb3+ doped silica fibre lasers in 1 μm region[J]. Electron. Lett., 1994, 30(11): 863~865
[10] Y. Jeong, J. Sahu, D. Payne et al.. Ytterbium-doped large-core fiber laser with 1.36 kW continuous-wave output power[J]. Opt. Express, 2004, 12(25): 6088~6092
[11] V. Fomin, A. Mashkin, M. Abramov et al.. 3 kW Yb fibre lasers with a single-mode output[C]. International Symposium on High-Power Fiber Lasers and Their Applications, 2006
[12] 光纤激光器的输出功率日益提升[OL]. http://www.laserfocusworld.com.cn/DeTC.asp id=25, 2010-07-23
[13] 赵鸿, 周寿桓, 朱辰 等. 大功率光纤激光器输出功率超过1.2 kW[J]. 中国激光, 2006, 33(10): 1359
Zhao Hong, Zhou Shouhuan, Zhu Chen et al.. High power fiber laser output power exceeds 1.2 kW[J]. Chinese J. Lasers, 2006, 33(10): 1359
[14] 楼祺洪, 何兵, 薛宇豪 等. 1.75 kW国产掺Yb双包层光纤激光器[J]. 中国激光, 2009, 36(5): 1277
Lou Qihong, He Bing, Xue Yuhao et al.. 1.75 kW fiber laser with homemade Yb-doped double cladding fiber[J]. Chinese J. Lasers, 2009, 36(5): 1277
[15] 李伟, 陈曦, 武子淳 等. 大功率光纤激光合成功率突破3 kW[J]. 强激光与粒子束, 2010, 22(2): 242
Li Wei, Chen Xi, Wu Zichun et al.. Combining power of high power fiber laser exceeds 3 kW[J]. High Power Laser and Particle Beams, 2010, 22(2): 242
[16] Y. Jeong, J. K. Sahu, R. B. Williams et al.. Ytterbium-doped large-core fibre laser with 272 W output power[J]. Electron. Lett., 2003, 39(13): 977~978
[17] Y. Jeong, J. K. Sahu, D. N. Payne et al.. Ytterbium-doped large-core fibre laser with 610 W of near diffraction-limited output power[J]. Electron. Lett., 2004, 40(24): 1527~1528
[18] Y. Jeong, J. K. Sahu, D. N. Payne et al.. Ytterbium-doped large-core fiber laser with 1 kW continuous-wave output power[J]. Electron. Lett., 2004, 40(8): 470~472
[19] J. Limpert, A. Liem, H. Zellmer. 500 W continuous-wave fibre laser with excellent beam quality[J]. Electron. Lett., 2003, 39(8): 645~647
[20] D. Jaque, J. C. Lagomacini, C. Jacinto et al.. Continuous-wave diode-pumped Ybglass laser with near 90% slope efficiency[J]. Appl. Phys. Lett., 2006, 89(12): 121101
[21] Y. Jeong, A. J. Boyland, J. K. Sahu et al.. Multi-kilowatt single-mode ytterbium-doped large-core fiber laser[J]. J. Opt. Soc. Korea, 2009, 13(4): 416~422
[22] A. S. Kurkov, V. I. Karpov, A. Yu Laptev et al.. Highly efficient cladding-pumped fibre laser based on an ytterbium-doped optical fibre and a fibre Bragg grating[J]. Quantum Electron., 1999, 29(6): 516~517
[23] Réal Vallée, Erik Bélanger, Bernard Déry et al.. Highly efficient and high-power Raman fiber laser based on broadband chirped fiber Bragg gratings[J]. J. Lightwave Technol., 2006, 24(12): 5039~5043
[24] A. S. Kurkov, D. A. Grukh, O. I. Medvedkov et al.. Ytterbium-doped fibre laser with a Bragg grating reflector written in a multimode fibre[J]. Quantum Electron., 2005, 35(4): 339~340
[25] Yan Feng, Luke R. Taylor, Domenico Bonaccini Calia. 150 W highly-efficient Raman fiber laser[J]. Opt. Express, 2009, 17(26): 23678~23683
[26] D. J. DiGiovanni. Tapered Fiber Bundles for Coupling Light Into and Out of Cladding Pumped Fiber Devices[P]. US Patent 5,864,644, 1999
[27] B. G. Fidric. Optical Couplers for Multimode Fibers[P]. US Patent 6,434,302 B1, 2002
[28] A. Kosterin, V. Temyanko, M. Fallahi et al.. Tapered fiber bundles for combining high-power diode lasers[J]. Appl. Opt., 2004, 43(19): 3893~3900
[29] Y. Shamir, Y. Sintov, M. Shtaif. Beam quality analysis and optimization in an adiabatic low mode tapered fiber beam combiner[J]. J. Opt. Soc. Am. B, 2010, 27(12): 2669~2676
[30] A. Wetter, M. Faucher, M. Lovelady et al.. Tapered fused-bundle splitter capable of 1 kW CW operation[C]. SPIE, 2007, 6453: 645301
[31] F. Mathieu, Benoit Sevigny, Roger Perreault et al.. All-fiber 32×1 pump combiner with high isolation for high power fiber laser[C]. CLEO/QELS, 2008, CMA5
[32] A. Wetter. Optical Fiber Component Package for High Power Dissipation[P]. US Patent 7,373,070 B2, 2008
[33] Marc F. Gonthier, Vachon Garneau. Multimode Fiber Outer Cladding Coupler for Multi-Clad Fibers[P]. US Patent 7,933,479 B2, 2011
[35] P. Yan, M. Gong. 1.1 kW ytterbium monolithic fiber laser with assembled end-pump scheme to couple high brightness single emitters[J]. IEEE Photon. Techol. Lett., 2010, 23(11): 697~699
[36] S. Yin, P. Yan, M. Gong. End-pumped 300 W continuous-wave ytterbium-doped all-fiber laser with master oscillator multi-stage power amplifiers configuration[J]. Opt. Express, 2008, 16(22): 17864~17869
[37] Hagop Injeyan, Gregory Goodno. High-Power Laser Handbook[M]. New York: McGraw-Hill, 2011. 520~526
[38] F. Gonthier. Optical Coupler Comprising Multimode Fibers and Method of Making the Same[P]. US Patent 2005/0,094,952 A1, 2005
[39] F. Gonthier. Optical Coupler Comprising Multimode Fibers and Method of Making the Same[P]. US Patent 7,046,875 B2, 2006
[40] D. J. Ripin, L. Goldberg. High efficiency side-coupling of light into optical fibres using imbedded V-grooves[J]. Electron. Lett., 1995, 31(25): 2204~2205
[41] L. Goldberg, D. J. Ripin. High-efficiency side-coupling of light into double-cladding fibers using imbedded V-grooves[C]. Optical Fiber Communications 1996, 1996, 91~92
[42] J. P. Koplow, Lew Goldberg, A. V. Dahv et al.. Compact 1-W Yb-doped double-cladding fiber amplifier using V-groove side-pumping[J]. IEEE Photon. Technol. Lett., 1998, 10(6): 793~795
[43] K. J. Snell. Multiple Emitter Side Pumping Method and Apparatus for Fiber Lasers[P]. US Patent 6,801,550 B1, 2004
[44] L. Goldberg, B. Cole, E. Snitzer. V-groove side-pumped 1.5 μm fiber amplifier[J]. Electron. Lett., 1997, 33(25): 2127~2129
[45] Li Cheng, Shen Deyuan, Song Jie et al.. Analysis of high-power double-clad fiber lasers side-pumped by multiple diode-lasers in V-groove configuration[C]. The Pacifice Rim Conference on Lasers and Electro-Optics, 1999, 3: 805~806
[46] J. P. Koplow, S. W. Moore, D. A. Kliner. A new method for side pumping of double-clad fiber sources[J]. IEEE J. Quantum Electron., 2003, 39(4): 529~540
[47] F. Hakimi, H. Hakimi. Side Pumped Optical Amplifiers and Lasers[P]. US Patent 6,370,297 B1, 2002
[48] P. Ou, P. Yan, M. Gong et al.. Studies of pump light leakage out of couplers for multi-coupler side-pumped Yb-doped double-clad fiber lasers[J]. Opt. Commun., 2004, 239(4): 421~428
[49] J. Xu, J. Lu, G. Kumar et al.. A non-fused fiber coupler for side-pumping of double-clad fiber lasers[J]. Opt. Commun., 2003, 220(4): 389~395
[51] Q. Xiao, P. Yan, S. Yin et al.. 100 W ytterbium-doped monolithic fiber laser with fused angle-polished side-pumping configuration[J]. Laser Phys. Lett., 2011, 8(2): 125~129
[52] R. Herda, A. Liem, B. Schnabel et al.. Efficient side-pumping of fibre lasers using binary gold diffraction gratings[J]. Electron. Lett., 2003, 39(3): 276~277
[53] F. Zhang, C. Wang, R. Geng et al.. Novel grating couplers for diode-bars multi-point side-pumping double-clad fiber[J]. Opt. Commun., 2007, 279(2): 346~355
[54] F. Zhang, C. Wang, T. Ning et al.. Asymmetric dual-side-grating coupler for high power side-pumping[J]. Opt. Commun., 2008, 281(10): 2883~2892
[55] F. Zhang, B. Yuan, C. Wang et al.. Side pumping scheme with a dual-sided grating coupler[J]. J. Opt., 2010, 12(1): 015501
[56] A. B. Grudinin, D. N. Payne, P. W. Turner et al.. Multi-Fiber Arrangements for High Power Fiber Lasers and Amplifiers[P]. US Patent 6,826,335 B1, 2004
[57] A. B. Grudinin, D. N. Payne, P. W. Turner et al.. Multi-Fiber Arrangement for High Power Fiber Lasers and Amplifiers[P]. US Patent 7,221,822 B2, 2007
[58] P. Dupriez. Advanced High Power Pulsed Fiber Laser Systems and Their Applications[D]. Southampton: Universty of Southampton, 2007. 18~19
[59] V. P. Gapontsev, V. Fomin, N. Platonov. Powerful Fiber Laser System[P]. US Patent 7,593,435 B2, 2009
[60] V. P.Gapontsev. Powerful Fiber Laser System[P]. US Patent 2009/0,092,157 A1, 2009
[61] V. P. Gapontsev, V. Fomin, N. Platonov. Powerful Fiber Laser System[P]. US Patent 2010/0,002,730 A1, 2010
[62] J. Yoonchan, J. Nilsson, K. Sahu et al.. Power scaling of single-frequency ytterbium-doped fiber master-oscillator power-amplifier sources up to 500 W[J]. IEEE J. Sel. Top. Quantum Electron., 2007, 13(3): 546~551
[63] R. Horley, S. Norman, M. Zervas. Progress and development in fiber laser technology[C]. SPIE, 2007, 6738: 67380K
[64] J. N. Maran, Y. Jeong, S. Yoo et al.. Progress in high-power single frequency master oscillator power amplifier[C]. SPIE, 2008, 7099: 70990X
[65] IPG Tests First 10 kW Singlemode Production Laser [OL]. http://optics.org/article/39511, 2009-06-17
[66] S. Norman, M. Zervas, A. Appleyard et al.. Latest development of high power fiber lasers in SPI[C]. SPIE, 2004, 5335: 229~230
[67] V.Gapontsev, D. Gapontsev, N. Platonov et al.. 2 kW CW ytterbium fiber laser with record diffraction-limited brightness[C]. Conference on Lasers and Electro-Optics Europe, 2005, 508
李杰, 陈子伦, 周航, 郭少锋, 许晓军. 高功率光纤激光器抽运耦合技术的现状和发展[J]. 激光与光电子学进展, 2012, 49(2): 020003. Li Jie, Chen Zilun, Zhou Hang, Guo Shaofeng, Xu Xiaojun. Status and Development of Pumping Technology for High Power Fiber Lasers[J]. Laser & Optoelectronics Progress, 2012, 49(2): 020003.