High Power Laser and Particle Beams, Volume. 32, Issue 12, 121001(2020)
High-power narrow-linewidth fiber laser technology
Figures & Tables(23)
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Table 1.
Typical progress of single frequency Yb-doped fiber oscillators
单频光纤振荡器研究进展
View tableView in ArticleTable 1.
Typical progress of single frequency Yb-doped fiber oscillators
单频光纤振荡器研究进展
fiber type doped ions year institution structure wavelength/nm power/mW linewidth/kHz Ref. silica fiber Tm 2017 Tianjin University DBR 1920 120 36 [ 63 ]Yb:YAG 2019 Shandong University DBR 1064 110 1300 [ 43 ]Nd 2020 SCUT DBR 1120 15 71.5 [ 44 ]phosphate fiber Yb 2004 NP Photonics DBR 1064.2 200 3 [ 57 ]Yb 2011 SCUT DBR 1064 400 <7 [ 53 ]Yb 2012 NP Photonics DBR 976 100 <3 [ 42 ]Yb 2013 SCUT DBR 1014 164 <7 [ 58 ]Yb 2013 SCUT DBR 1083 100 <2 [ 59 ]Yb 2016 SCUT DBR 1120 62 5.7 [ 60 ]Er-Yb 2003 − DBR 1560 200 1.75 [ 64 ]Er-Yb 2005 The University of Arizona DBR 1550 1600 − [ 65 ]Er-Yb 2005 The University of Arizona DBR 1535 1900 − [ 66 ]Er-Yb(PCF) 2006 The University of Arizona DFB 1534 2300 − [ 45 ]Er-Yb 2008 The University of Arizona DFB 1536 165 − [ 40 ]Er-Yb 2010 SIOM DBR 1535 100 <5 [ 61 ]Er-Yb 2010 SCUT DBR 1535 306 1.6 [ 62 ]Er-Yb 2013 − DBR 1538 550 <60 [ 54 ]germanate fiber Tm 2007 NP Photonics DFB 1893 50 3 [ 39 ]Tm 2018 SCUT DBR 1950 617 12.5 [ 46 ]Tm 2019 Zhejiang University ring cavity 1957 400 20 [ 52 ]Tm 2019 University of Southampton DBR 1952 1520 − [ 47 ]silicate fiber Tm 2009 AdValue Photonics DFB 1950 40 <3 [ 41 ]
Table 2.
Typical progress of single frequency Yb-doped fiber amplifiers (Non: nonlinearly polarized state, NA: not available, ATF: acoustically tailored fiber, T-YDF: tapered Yb-doped fiber, LMA: large mode area)
单频掺镱光纤放大器研究进展
View tableView in ArticleTable 2.
Typical progress of single frequency Yb-doped fiber amplifiers (Non: nonlinearly polarized state, NA: not available, ATF: acoustically tailored fiber, T-YDF: tapered Yb-doped fiber, LMA: large mode area)
单频掺镱光纤放大器研究进展
year institution configuration power/W wavelength/nm PER/dB M 2approaches Ref. 2005 University of Southampton bulk 264 1060 16 <1.1 counter-pumping [ 68 ]2007 University of Southampton bulk 511 1060 Non 1.6 LMA fiber [ 69 ]2007 Corning bulk 502 1064 Non 1.4 bi-directionally pumping [ 70 ]2011 AFRL bulk 494 1064 15 <1.3 ATF and counter-pumping [ 72 ]2011 University of Michigan bulk 511 1064 15 1.19 chirally-coped-core fiber [ 71 ]2014 AFRL bulk 811 1064 NA <1.2 ATF and thermal gradient [ 73 ]2008 OFS Laboratories all-fiber 194 1083 Non 1.2 acoustically-designed fiber [ 74 ]2011 AFRL all-fiber 203 1065 NA − thermal gradient and gain competition [ 80 ]2012 Laser Zentrum Hannover all-fiber 301 1064 Non − counter-pumping and thermal gradient [ 75 ]2012 NUDT all-fiber 310 1064 Non 1.3 LMA fiber [ 81 ]2013 NUDT all-fiber 332 1064 21 1.4 LMA fiber [ 76 ]2013 SIOM all-fiber 170 1064 NA 1.02 strain gradient and thermal gradient [ 77 ]2017 NUDT all-fiber 414 1064 16.9 1.34 LMA fiber and strain gradient [ 78 ]2020 NUDT all-fiber 550 1030 Non 1.47 tapered fiber [ 79 ]2019 LIGO Laboratories all-fiber 178 1064 19 <1.32 specialty LMA fiber [ 15 ]2019 Laser Zentrum Hannover all-fiber 200 1064 19 − LMA fiber and thermal gradient [ 82 ]2020 University of Bordeaux all-fiber 365 1064 17 <1.1 LMA fiber and short fiber length [ 83 ]
Table 3.
Progress of high power narrow-linewidth fiber lasers based on narrow-linewidth fiber oscillators
基于窄线宽光纤振荡器的高功率窄线宽光纤激光研究进展
View tableView in ArticleTable 3.
Progress of high power narrow-linewidth fiber lasers based on narrow-linewidth fiber oscillators
基于窄线宽光纤振荡器的高功率窄线宽光纤激光研究进展
year institution power/kW linewidth M 2PER/dB Ref 2015 HFB Photonics 2.05 75 GHz <1.4 Non [ 106 ]2015 Tianjin University 0.52 30 GHz <1.09 >18 [ 113 ]2016 CAEP 2.9 0.31 nm − Non [ 107 ]2017 NUDT 1.018 0.3 nm <1.24 14 [ 114 ]2017 Tsinghua University 3.12 2.5 nm 1.58 Non [ 111 ]2017 CAEP 1.093 6.5 GHz 1.1 14.5 [ 108 ]2019 Tsinghua University 2.19 0.0865 nm 1.46 Non [ 112 ]2020 CAEP 3.08 0.2 nm <1.45 11.6 [ 22 ]
Table 4.
Progress of high power narrow-linewidth fiber lasers based on phase modulation techniques
基于相位调制技术的高功率窄线宽光纤激光研究进展
View tableView in ArticleTable 4.
Progress of high power narrow-linewidth fiber lasers based on phase modulation techniques
基于相位调制技术的高功率窄线宽光纤激光研究进展
modulation methods year institution power/kW linewidth M 2PER/dB Ref sine modulation 2011 Fibertek, Inc. 1 <0.5 GHz <1.4 Non [ 121 ]2016 NUDT 1.89 45 GHz <1.3 15.5 [ 122 ]WNS modulation 2017 NUDT 2.43 0.255 nm − 18.3 [ 123 ]2018 NUDT 3.94 0.89 nm 1.86 Non [ 24 ]2018 CAEP 2.5 54 GHz <1.21 Non [ 138 ]2018 CAEP 3.5 0.38 nm 1.9 Non [ 124 ]2019 CAEP 1.5 13 GHz 1.14 13 [ 139 ]2019 NUDT 0.827 1.8 GHz − 12 [ 140 ]2019 SIOM 3.01 48 GHz 1.17 Non [ 127 ]2019 CAEP 2.62 32 GHz <1.3 14.2 [ 125 ]2019 CAEP 3.7 0.3 nm <1.36 Non [ 126 ]2020 NUDT 4.09 0.9 nm 1.05 Non − PRBS modulation 2014 AFRL 1.17 3 GHz 1.2 Non [ 129 ]2015 AFRL 1.47 5 GHz 1.17 Non [ 141 ]2016 AFRL 1 2.3 GHz <1.2 Non [ 130 ]2016 MIT 3.1 12 GHz <1.15 10 [ 23 ]2018 University of Michigan 2.2 20 GHz 1.09 Non [ 134 ]2020 SIOM 1.27 2.2 GHz <1.2 Non [ 128 ]2020 DSO National Laboratories, Singapore 1 6.9 GHz 1.19 Non [ 135 ]unavailable phase modulation 2016 Jena 3 0.17 1.3 Non [ 136 ]2017 Jena 3.5 0.18 1.3 Non [ 137 ]2018 Jena 4.4 − − Non [ 26 ]2018 IPG 2.5 30 GHz <1.1 Non [ 27 ]
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Wenchang Lai, Pengfei Ma, Hu Xiao, Wei Liu, Can Li, Man Jiang, Jiangming Xu, Rongtao Su, Jinyong Leng, Yanxing Ma, Pu Zhou. High-power narrow-linewidth fiber laser technology[J]. High Power Laser and Particle Beams, 2020, 32(12): 121001
Paper Information
Category: Fiber Laser
Received: Jul. 2, 2020
Accepted: --
Published Online: Jan. 6, 2021
The Author Email: Zhou Pu (zhoupu203@163.com)
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