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    Journals >Chinese Journal of Lasers >Volume 46 >Issue 5 >Page 0508013 > Article
    • Chinese Journal of Lasers
    • Vol. 46, Issue 5, 0508013 (2019)
    Research Advances in Mode-Locked Fiber Lasers Based on Nonlinear Loop Mirror
    Jiaqi Zhou1, Weiwei Pan1, Lei Zhang2, Xijia Gu, and Yan Feng1、*
    Author Affiliations
  • 1Shanghai Institute of Optics and Fine Mechanics, Chinese Academy of Sciences, Shanghai 201800, China
  • 2PreciLasers Co., Ltd., Shanghai 201800, China
    • show less
    DOI: 10.3788/CJL201946.0508013 Cite this Article Set citation alerts
    Jiaqi Zhou, Weiwei Pan, Lei Zhang, Xijia Gu, Yan Feng. Research Advances in Mode-Locked Fiber Lasers Based on Nonlinear Loop Mirror[J]. Chinese Journal of Lasers, 2019, 46(5): 0508013 Copy Citation Text show less
    Structural diagram of NOLM/NALM
    Fig. 1. Structural diagram of NOLM/NALM
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    Schematics of figure-of-8 and figure-of-9 cavities. (a) Schematic of figure-of-8 mode-locked fiber laser; (b) schematic of figure-of-9 mode-locked fiber laser; (c) calculated round trip transmission through NOLM/NALM device as function of nonlinear phase difference in loop (corresponding to figure-of-8 cavity); (d) calculated round trip reflection through NOLM/NALM device as function of nonlinear phase difference in loop (corresponding to figure-of-9 cavity)
    Fig. 2. Schematics of figure-of-8 and figure-of-9 cavities. (a) Schematic of figure-of-8 mode-locked fiber laser; (b) schematic of figure-of-9 mode-locked fiber laser; (c) calculated round trip transmission through NOLM/NALM device as function of nonlinear phase difference in loop (corresponding to figure-of-8 cavity); (d) calculated round trip reflection through NOLM/NALM device as function of nonlinear phase difference in loop (corresponding to figure-of-9 cavity)
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    Experimental setup for non-PM NOLM/NALM dissipative soliton fiber laser
    Fig. 3. Experimental setup for non-PM NOLM/NALM dissipative soliton fiber laser
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    Experimental setup for PM figure-of-8 mode-locked fiber laser with dual-gain
    Fig. 4. Experimental setup for PM figure-of-8 mode-locked fiber laser with dual-gain
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    Output characterization of PM figure-of-8 mode-locked fiber laser with dual-gain. (a) Spectrum; (b) pulse train; (c) frequency spectrum; (d) autocorrelation signal
    Fig. 5. Output characterization of PM figure-of-8 mode-locked fiber laser with dual-gain. (a) Spectrum; (b) pulse train; (c) frequency spectrum; (d) autocorrelation signal
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    Output power stability test of PM figure-of-8 mode-locked fiber laser in duration of 24 h
    Fig. 6. Output power stability test of PM figure-of-8 mode-locked fiber laser in duration of 24 h
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    PM figure-of-9 mode-locked fiber laser. (a) Experimental setup; (b) principle diagram of phase shifter
    Fig. 7. PM figure-of-9 mode-locked fiber laser. (a) Experimental setup; (b) principle diagram of phase shifter
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    Experimental setup for compact figure-of-9 mode-locked fiber laser[37]
    Fig. 8. Experimental setup for compact figure-of-9 mode-locked fiber laser[37]
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    Output characterization of PM figure-of-9 1550 nm femtosecond fiber laser. (a) Spectrum; (b) pulse train; (c) frequency spectrum; (d) autocorrelation signal
    Fig. 9. Output characterization of PM figure-of-9 1550 nm femtosecond fiber laser. (a) Spectrum; (b) pulse train; (c) frequency spectrum; (d) autocorrelation signal
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    Output power stability test results of PM figure-of-9 1550 nm femtosecond fiber laser. (a) 0-45 ℃ high-low temperature test; (b) long-term test in duration of 15 h
    Fig. 10. Output power stability test results of PM figure-of-9 1550 nm femtosecond fiber laser. (a) 0-45 ℃ high-low temperature test; (b) long-term test in duration of 15 h
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    Output characterization of PM figure-of-9 1064 nm picosecond fiber laser. (a) Spectrum; (b) pulse train; (c) frequency spectrum; (d) autocorrelation signal
    Fig. 11. Output characterization of PM figure-of-9 1064 nm picosecond fiber laser. (a) Spectrum; (b) pulse train; (c) frequency spectrum; (d) autocorrelation signal
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    Self-starting test of PM figure-of-9 1064 nm picosecond fiber laser
    Fig. 12. Self-starting test of PM figure-of-9 1064 nm picosecond fiber laser
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    Miniaturized optical frequency comb module[39]. (a) Physical map of frequency comb; (b) principle diagram of device
    Fig. 13. Miniaturized optical frequency comb module[39]. (a) Physical map of frequency comb; (b) principle diagram of device
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    Principle of all-fiber CPA technology
    Fig. 14. Principle of all-fiber CPA technology
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    Abstract
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    References (48)
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    Jiaqi Zhou, Weiwei Pan, Lei Zhang, Xijia Gu, Yan Feng. Research Advances in Mode-Locked Fiber Lasers Based on Nonlinear Loop Mirror[J]. Chinese Journal of Lasers, 2019, 46(5): 0508013
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    Paper Information
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