Progress on High-Power Low-Noise Continuous-Wave Single-Frequency All-Solid-State Lasers

Kuanshou Zhang; Huadong Lu; Yuanji Li; Jinxia Feng

doi:10.3788/CJL202148.0501002

Journals >Chinese Journal of Lasers >Volume 48 >Issue 5 >Page 0501002 > Article

Chinese Journal of Lasers
Vol. 48, Issue 5, 0501002 (2021)

Progress on High-Power Low-Noise Continuous-Wave Single-Frequency All-Solid-State Lasers

Kuanshou Zhang^1,2,*, Huadong Lu^1,2, Yuanji Li^1,2, and Jinxia Feng^1,2

Author Affiliations

¹State Key Laboratory of Quantum Optics and Quantum Optics Devices, Institute of Opto-Electronics, Shanxi University, Taiyuan, Shanxi 0 30006, China

²Collaborative Innovation Center of Extreme Optics, Shanxi University, Taiyuan, Shanxi 0 30006, China

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DOI: 10.3788/CJL202148.0501002 Cite this Article Set citation alerts

Kuanshou Zhang, Huadong Lu, Yuanji Li, Jinxia Feng. Progress on High-Power Low-Noise Continuous-Wave Single-Frequency All-Solid-State Lasers[J]. Chinese Journal of Lasers, 2021, 48(5): 0501002 Copy Citation Text

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Fig. 1. Thermal focal length of laser crystal versus incident pump power at different pump schemes and boundary temperatures of laser crystal^[38]

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Fig. 2. 1.34μm output power versus boundary temperature of laser crystal under dual-end pump^[38]

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Fig. 3. Temperature distributions in laser crystal under different cooling schemes ^[40]

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Fig. 4. Critical nonlinear conversion coefficient versus output transmission of coupling mirror for stable SLM operation of high-power 1.34μm Nd∶YVO₄ laser ^[49]

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Fig. 5. Continuous tuning range of laser under different intra-cavity losses L and nonlinear losses η^[50]. (a) L=5.8% , η=1.87%; (b) L=9.8%, η=1.2%

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Fig. 6. Experimental setup of continuous wave single-frequency Nd∶YVO₄ laser polarized and dual-end pumped by 880nm LD^[41]

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Fig. 7. Experimental setup of high-power continuous wave single-frequency Nd∶YVO₄ green laser by self-compensation of astigmatisms ^[52]

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Fig. 8. Output powers of 1.064μm and 532nm lasers versus output transmission of coupling mirror^[57]

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Fig. 9. Experimental setup of dual-end-pumped two-stage MOPA^[65]

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Fig. 10. Experimental setup of all-solid-state continuous wave 1.064μm single-frequency laser with output power of 101W^[66]

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Fig. 11. Measured relative intensity and phase noise of continuous wave single-frequency Er, Yb∶YAB laser at 1.55μm^[40]

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Fig. 12. Relative intensity noise spectra of single-frequency 1.064μm laser under different nonlinear conversion coefficients η^[71]

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Fig. 13. Intensity noise spectra of laser^[73]. (a) L=450mm, η=0; (b) L=1050mm, η=0; (c) L=1050mm, η=0.45%

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Fig. 14. Intensity noise of output laser from MZI versus analysis frequency under different R and T_lock=85% ^[74]

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Fig. 15. Output powers of 1.34μm and 671nm lasers versus temperature of LBO crystal ^[49]

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Fig. 16. Experimental setup of all-solid-state continuous wave single-frequency 1.55 μm Er,Yb∶YAB laser^[40]

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Fig. 17. Experimental setup of all-solid-state continuous wave single-frequency tunable Ti: sapphire laser^[86]

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Fig. 18. Experimental setup of self-injection locked Ti: sapphire laser ^[91]

Kuanshou Zhang, Huadong Lu, Yuanji Li, Jinxia Feng. Progress on High-Power Low-Noise Continuous-Wave Single-Frequency All-Solid-State Lasers[J]. Chinese Journal of Lasers, 2021, 48(5): 0501002

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