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Photonics Research, Volume. 6, Issue 11, 996(2018)

Facile active control of a pulsed erbium-doped fiber laser using modulation depth tunable carbon nanotubes

Xintong Xu1,2, Shuangchen Ruan1、*, Jianpang Zhai1, Ling Li1, Jihong Pei2, and Zikang Tang3
Author Affiliations
  • 1Shenzhen Key Laboratory of Laser Engineering, Guangdong Provincial Key Laboratory of Micro/Nano Optomechatronics Engineering, Shenzhen University, Shenzhen 518060, China
  • 2College of Information Engineering, ATR National Defence S&T Key Laboratory, Shenzhen University, Shenzhen 518060, China
  • 3Institute of Applied Physics & Materials Engineering, Faculty of Science and Technology, University of Macau, Macau, China
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    Schematic diagram of the erbium-doped fiber laser.

    Fig. 1. Schematic diagram of the erbium-doped fiber laser.

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    (a) Scanning electron microscopy image of pristine AFI single crystals. (b) Framework structure of an AFI single crystal viewed along the [001] direction. (c) SWCNTs are sketched inside the channels of AFI. (d) Raman spectrum of the SWCNTs@AFI single crystal.

    Fig. 2. (a) Scanning electron microscopy image of pristine AFI single crystals. (b) Framework structure of an AFI single crystal viewed along the [001] direction. (c) SWCNTs are sketched inside the channels of AFI. (d) Raman spectrum of the SWCNTs@AFI single crystal.

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    (a) Experimental setup for the measurement of saturable absorption of SWCNTs@AFI. Dots are the measured data and the red line is the data fitting. Pulse excitation wavelength at 1.5 μm with different polarization directions (b) E∥C and (c) E⊥C. (d) Polarized absorption spectra of the well-aligned carbon nanotube arrays under different polarization angles.

    Fig. 3. (a) Experimental setup for the measurement of saturable absorption of SWCNTs@AFI. Dots are the measured data and the red line is the data fitting. Pulse excitation wavelength at 1.5 μm with different polarization directions (b) EC and (c) EC. (d) Polarized absorption spectra of the well-aligned carbon nanotube arrays under different polarization angles.

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    Typical oscilloscope traces of the Q-switching pulse trains under different polarization angles of (a) 0°, (b) 8°, (c) 14°, and (d) 20°.

    Fig. 4. Typical oscilloscope traces of the Q-switching pulse trains under different polarization angles of (a) 0°, (b) 8°, (c) 14°, and (d) 20°.

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    Pulse duration and average output power as functions of polarization angle.

    Fig. 5. Pulse duration and average output power as functions of polarization angle.

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    Output characteristic of the EDFL operated in the Q-switching state. (a) Single pulse profile. (b) Emission spectrum.

    Fig. 6. Output characteristic of the EDFL operated in the Q-switching state. (a) Single pulse profile. (b) Emission spectrum.

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    Saturable absorption properties of the SWCNTs@AFI SA under different polarization angles of (a) 20°, (b) 40°, and (c) 70°.

    Fig. 7. Saturable absorption properties of the SWCNTs@AFI SA under different polarization angles of (a) 20°, (b) 40°, and (c) 70°.

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    Output characteristic of the EDFL operated in the mode-locking state. (a) Pulse train. (b) Emission spectrum. (c) Single pulse profile. (d) Radiofrequency spectrum.

    Fig. 8. Output characteristic of the EDFL operated in the mode-locking state. (a) Pulse train. (b) Emission spectrum. (c) Single pulse profile. (d) Radiofrequency spectrum.

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    Optical spectrum and corresponding single pulse profile of mode-locking under different polarization angles of (a) 46°, (b) 52°, (c) 60°, and (d) 70°.

    Fig. 9. Optical spectrum and corresponding single pulse profile of mode-locking under different polarization angles of (a) 46°, (b) 52°, (c) 60°, and (d) 70°.

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    (a) Emission spectrum, (b) autocorrelation trace, (c) pulse train, and (d) radiofrequency spectrum of two bound soliton EDFL.

    Fig. 10. (a) Emission spectrum, (b) autocorrelation trace, (c) pulse train, and (d) radiofrequency spectrum of two bound soliton EDFL.

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    (a) CW laser output spectrum of the EDFL without a carbon nanotube SA in the cavity. (b) Laser intensity as a function of time.

    Fig. 11. (a) CW laser output spectrum of the EDFL without a carbon nanotube SA in the cavity. (b) Laser intensity as a function of time.

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    Xintong Xu, Shuangchen Ruan, Jianpang Zhai, Ling Li, Jihong Pei, Zikang Tang, "Facile active control of a pulsed erbium-doped fiber laser using modulation depth tunable carbon nanotubes," Photonics Res. 6, 996 (2018)

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    Paper Information

    Category: Lasers and Laser Optics

    Received: Jun. 12, 2018

    Accepted: Aug. 31, 2018

    Published Online: Oct. 11, 2018

    The Author Email: Shuangchen Ruan (scruan@szu.edu.cn)

    DOI:10.1364/PRJ.6.000996

    Topics

    laser devices and laser physics
    Lasers and Laser Optics
    Laser physics
    laser manufacturing
    Instrumentation, Measurement and Metrology