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    Journals >Acta Optica Sinica >Volume 41 >Issue 1 >Page 0114002 > Article
    • Acta Optica Sinica
    • Vol. 41, Issue 1, 0114002 (2021)
    Research Progress of Single-Frequency Fiber Laser
    Changsheng Yang1、3, Xu Cen1, Shanhui Xu1、2、3, and Zhongmin Yang1、2、3、4、*
    Author Affiliations
  • 1State Key Laboratory of Luminescent Materials and Devices, South China University of Technology, Guangzhou, Guangdong 510640, China
  • 2School of Physics and Optoelectronics, South China University of Technology, Guangzhou, Guangdong 510640, China
  • 3Guangdong Engineering Technology Research and Development Center of Special Optical Fiber Materials and Devices, Guangzhou, Guangdong 510640, China
  • 4Guangdong Provincial Key Laboratory of Fiber Laser Materials and Applied Techniques, South China University of Technology, Guangzhou, Guangdong 510640, China
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    DOI: 10.3788/AOS202141.0114002 Cite this Article Set citation alerts
    Changsheng Yang, Xu Cen, Shanhui Xu, Zhongmin Yang. Research Progress of Single-Frequency Fiber Laser[J]. Acta Optica Sinica, 2021, 41(1): 0114002 Copy Citation Text show less
    Experimental setup of 978-nm ultrashort cavity DBR single-frequency fiber laser[29]
    Fig. 1. Experimental setup of 978-nm ultrashort cavity DBR single-frequency fiber laser[29]
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    Experimental setup of short linear cavity Yb3+-doped single-frequency phosphate fiber laser[11]
    Fig. 2. Experimental setup of short linear cavity Yb3+-doped single-frequency phosphate fiber laser[11]
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    Experimental setup of single-frequency amplifier[31]
    Fig. 3. Experimental setup of single-frequency amplifier[31]
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    Output power and backward power versus pump power[34]
    Fig. 4. Output power and backward power versus pump power[34]
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    Experimental setup of 1120 nm linearly-polarized DBR single-frequency fiber laser[12]
    Fig. 5. Experimental setup of 1120 nm linearly-polarized DBR single-frequency fiber laser[12]
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    Schematic diagram of linearly frequency-modulated pulsed single-frequency fiber laser at 1083 nm[39]
    Fig. 6. Schematic diagram of linearly frequency-modulated pulsed single-frequency fiber laser at 1083 nm[39]
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    Experimental setup of single-frequency all-fiber pulsed MOPA[40]
    Fig. 7. Experimental setup of single-frequency all-fiber pulsed MOPA[40]
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    Structural diagram of 1.6 μm linearly-polarized DBR single-frequency fiber laser[14]
    Fig. 8. Structural diagram of 1.6 μm linearly-polarized DBR single-frequency fiber laser[14]
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    Schematic of high-power single-frequency Er3+/Yb3+ co-doped fiber amplifier[48]
    Fig. 9. Schematic of high-power single-frequency Er3+/Yb3+ co-doped fiber amplifier[48]
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    Output power of high-power EYDFA pumped by 940 nm laser[48]
    Fig. 10. Output power of high-power EYDFA pumped by 940 nm laser[48]
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    Output power versus pump power with input auxiliary power of 0, 200, 400, 500, and 600 mW[49]
    Fig. 11. Output power versus pump power with input auxiliary power of 0, 200, 400, 500, and 600 mW[49]
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    Experimental setup diagram of intensity noise suppression of single-frequency fiber laser based on SOA and optoelectronic negative feedback[52]
    Fig. 12. Experimental setup diagram of intensity noise suppression of single-frequency fiber laser based on SOA and optoelectronic negative feedback[52]
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    Experimental setup diagram of frequency noise suppression of single-frequency fiber laser based on SOA and optical feedback[56]
    Fig. 13. Experimental setup diagram of frequency noise suppression of single-frequency fiber laser based on SOA and optical feedback[56]
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    Schematic diagram of 100-Hz-level-linewidth single-frequency fiber laser[57]
    Fig. 14. Schematic diagram of 100-Hz-level-linewidth single-frequency fiber laser[57]
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    Laser linewidth of self-injection locked single-frequency fiber laser[58]
    Fig. 15. Laser linewidth of self-injection locked single-frequency fiber laser[58]
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    Experimental setup of self-injection locked tunable single-frequency fiber laser[61]
    Fig. 16. Experimental setup of self-injection locked tunable single-frequency fiber laser[61]
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    Structural diagram of multi-wavelength passively Q-switched single-frequency fiber laser[65]
    Fig. 17. Structural diagram of multi-wavelength passively Q-switched single-frequency fiber laser[65]
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    Structural diagram of single-frequency MOPA laser based on single-mode pulse[66]
    Fig. 18. Structural diagram of single-frequency MOPA laser based on single-mode pulse[66]
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    Simulated and experimental results of output powers versus pump power for different pump wavelengths[15]
    Fig. 19. Simulated and experimental results of output powers versus pump power for different pump wavelengths[15]
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    Diagram of single-frequency Tm3+-doped silica fiber laser based on cascaded SMS fiber devices[10]
    Fig. 20. Diagram of single-frequency Tm3+-doped silica fiber laser based on cascaded SMS fiber devices[10]
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    Experimental setup diagram of four-stage single-frequency Tm3+-doped fiber amplifier[71]
    Fig. 21. Experimental setup diagram of four-stage single-frequency Tm3+-doped fiber amplifier[71]
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    Power of 1950 nm linear polarization single-frequency fiber laser versus pump power at 1610 nm[75]. Inset: PERs at different output powers
    Fig. 22. Power of 1950 nm linear polarization single-frequency fiber laser versus pump power at 1610 nm[75]. Inset: PERs at different output powers
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    Diagram of two-stage power amplifier[82]. Inset: cross-section of gain fiber and picture of experimental device
    Fig. 23. Diagram of two-stage power amplifier[82]. Inset: cross-section of gain fiber and picture of experimental device
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    Diagram of 1200 nm Ho3+-doped single-frequency ZBLAN fiber laser[89]
    Fig. 24. Diagram of 1200 nm Ho3+-doped single-frequency ZBLAN fiber laser[89]
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    Schematic diagram of DFB single-frequency laser[88]
    Fig. 25. Schematic diagram of DFB single-frequency laser[88]
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    Changsheng Yang, Xu Cen, Shanhui Xu, Zhongmin Yang. Research Progress of Single-Frequency Fiber Laser[J]. Acta Optica Sinica, 2021, 41(1): 0114002
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