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    Journals >Acta Optica Sinica >Volume 43 >Issue 15 >Page 1514001 > Article
    • Acta Optica Sinica
    • Vol. 43, Issue 15, 1514001 (2023)
    Performance Control Techniques of High-Power Linearly Polarized Yb-Doped Fiber Lasers
    Ping Yan1、2、*, Yulun Wu1、2, Dan Li1、2, Yi Wang3, Qirong Xiao1、2, and Mali Gong1、2
    Author Affiliations
  • 1Key Laboratory of Photonics Control Technology of the Ministry of Education, Department of Precision Instrument, Tsinghua University, Beijing 100084, China
  • 2State Key Laboratory of Precision Measurement Technology and Instruments, Department of Precision Instrument, Tsinghua University, Beijing 100084, China
  • 3Weiyang College, Tsinghua University, Beijing 100084, China
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    DOI: 10.3788/AOS230733 Cite this Article Set citation alerts
    Ping Yan, Yulun Wu, Dan Li, Yi Wang, Qirong Xiao, Mali Gong. Performance Control Techniques of High-Power Linearly Polarized Yb-Doped Fiber Lasers[J]. Acta Optica Sinica, 2023, 43(15): 1514001 Copy Citation Text show less
    Choosing slow-axis linearly polarized laser output by coiling fiber[48]
    Fig. 1. Choosing slow-axis linearly polarized laser output by coiling fiber[48]
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    Realizing linearly polarized laser output by orthogonal splicing[49]
    Fig. 2. Realizing linearly polarized laser output by orthogonal splicing[49]
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    Calculated bending loss curves relative to polarization[51]
    Fig. 3. Calculated bending loss curves relative to polarization[51]
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    Polarization choosing of super large mode area PM fiber by coiling[53]
    Fig. 4. Polarization choosing of super large mode area PM fiber by coiling[53]
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    Comparison of output PER under 3 kW and 5 kW for two pumping schemes[54]. (a) 3 kW; (b) 5 kW
    Fig. 5. Comparison of output PER under 3 kW and 5 kW for two pumping schemes[54]. (a) 3 kW; (b) 5 kW
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    Realizing linearly polarized fiber laser output by active polarization control method[8]
    Fig. 6. Realizing linearly polarized fiber laser output by active polarization control method[8]
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    Realizing single frequency linearly polarized fiber laser output by combining PBS and single mode fiber[55]
    Fig. 7. Realizing single frequency linearly polarized fiber laser output by combining PBS and single mode fiber[55]
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    Effective refractive index and birefringence of all the PM fiber modes[58]. (a) Effective refractive index; (b) birefringence
    Fig. 8. Effective refractive index and birefringence of all the PM fiber modes[58]. (a) Effective refractive index; (b) birefringence
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    Specialty polarization maintaining photonic crystal fiber[59]
    Fig. 9. Specialty polarization maintaining photonic crystal fiber[59]
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    Asymmetric core polarization maintaining fiber[60]
    Fig. 10. Asymmetric core polarization maintaining fiber[60]
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    Sinusoidal signal phase modulation[62]
    Fig. 11. Sinusoidal signal phase modulation[62]
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    Linearly polarized fiber oscillator with 2 m cavity length[12]
    Fig. 12. Linearly polarized fiber oscillator with 2 m cavity length[12]
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    Single mode-multi mode-single mode oscillator construction[9]
    Fig. 13. Single mode-multi mode-single mode oscillator construction[9]
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    3.96 kW bidirectional pumping configuration[20]
    Fig. 14. 3.96 kW bidirectional pumping configuration[20]
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    Schematic of AM and FM combined injection[68]
    Fig. 15. Schematic of AM and FM combined injection[68]
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    3.25 kW spectrum evolution without SBS and self-pulsing[19]
    Fig. 16. 3.25 kW spectrum evolution without SBS and self-pulsing[19]
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    Self-pulsing suppressed single frequency seed by two stage phase modulation[17]
    Fig. 17. Self-pulsing suppressed single frequency seed by two stage phase modulation[17]
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    SBS suppression by using tapered polarization-maintaining fiber in amplifiers[16]
    Fig. 18. SBS suppression by using tapered polarization-maintaining fiber in amplifiers[16]
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    Investigation of impact on SRS under different seed time domain stability[77]
    Fig. 19. Investigation of impact on SRS under different seed time domain stability[77]
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    Mode selection by coiling fiber in the main amplifier stage[10]
    Fig. 20. Mode selection by coiling fiber in the main amplifier stage[10]
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    TMI threshold test results under forward and backward pumping[20]
    Fig. 21. TMI threshold test results under forward and backward pumping[20]
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    915 nm LD pumped linearly polarized fiber laser with high power seed injection[67]
    Fig. 22. 915 nm LD pumped linearly polarized fiber laser with high power seed injection[67]
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    TMI suppression by pumping modulation[89]
    Fig. 23. TMI suppression by pumping modulation[89]
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    YearInstitutionStructureWavelength /nmPower /kW3 dB linewidthPER /dBM2Ref
    2017CAEPFOL-MOPA10641.090.024 nm14.51.18
    2017NUDTFOL-MOPA10641.020.3 nm141.249
    2017NUDTSFL-MOPA10642.430.255 nm18.3/10
    2018IPGSFL-MOPA106420.113 nm>20<1.111
    2018NUDTFOL-MOPA10641.10.177 nm13.81.2512
    2019CAEPSFL-MOPA10642.620.121 nm14.2<1.313
    2019CAEPSFL-MOPA10641.50.049 nm>131.1414
    2020CAEPFOL-MOPA10643.080.2 nm>11.61.4515
    2020NUDTSFL-MOPA10640.3<0.035 pm>10.61.2616
    2020CAEPSFL-MOPA10642.50.121 nm141.317
    2020U-BordeauxSFL-MOPA10640.3650.05 nm17<1.118
    2021CAEPSFL-MOPA10643.25~0.075 nm151.2219
    2022NUDTSFL-MOPA10643.960.62 nm13.91.4120
    2022CAEPSFL-MOPA10644.450.08 nm17.71.2821
    2022NUDTSFL-MOPA10644.50.33 nm10.31.5522
    Table 1. Research development of linearly polarized Yb-doped fiber lasers
    Abstract
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    Ping Yan, Yulun Wu, Dan Li, Yi Wang, Qirong Xiao, Mali Gong. Performance Control Techniques of High-Power Linearly Polarized Yb-Doped Fiber Lasers[J]. Acta Optica Sinica, 2023, 43(15): 1514001
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