Investigation of temperature distribution and 2.79 μm laser performance on the Er:YSGG single crystal fiber

被引:3
作者
Han, Zhiyuan [1 ,2 ]
Sun, Dunlu [1 ,3 ]
Zhang, Huili [1 ,3 ]
Luo, Jianqiao [1 ,3 ]
Quan, Cong [1 ,2 ]
Hu, Lunzhen [1 ,2 ]
Dong, Kunpeng [1 ,2 ]
Chen, Yuwei [1 ,2 ]
Cheng, Maojie [1 ,3 ]
机构
[1] Chinese Acad Sci, Crystal Lab, Anhui Inst Opt & Fine Mech, Hefei Inst Phys Sci,Laser Technol Res Ctr, Hefei 230031, Peoples R China
[2] Univ Sci & Technol China, Hefei 230026, Peoples R China
[3] Adv Laser Technol Lab Anhui Prov, Hefei 230037, Peoples R China
来源
OPTICS COMMUNICATIONS | 2022年 / 502卷
基金
中国国家自然科学基金;
关键词
Er:YSGG single crystal fiber; Thermal distribution simulation; Beam quality factor; Mid-infrared laser; OPTICAL PARAMETRIC OSCILLATOR; HIGH-POWER; M EMISSION; GROWTH; ENERGY; ND;
D O I
10.1016/j.optcom.2021.127426
中图分类号
O43 [光学];
学科分类号
070207 ; 0803 ;
摘要
We demonstrate the temperature distribution and 2.79 mu m laser performance in a high-quality Er:YSGG single crystal fiber (SCF) with size of Phi 0.85x8 mm(3) for the first time. Compared with 2x2x8 mm(3) Er:YSGG bulk crystal, the simulation results show that the center maximum temperature of Er:YSGG SCF is much lower, and the temperature rising and total thermal deformation are evidently reduced, indicating that the SCF possesses more efficient thermal dissipation. Under 970 nm laser diode pumping, a maximum output power of 636 mW with slope efficiency of 20.2% is realized. More importantly, a high beam quality factors M-x(2)/M-y(2) of 1.28/1.29 is obtained, which is close to the fundamental TEM00 mode, suggesting that the Er:YSGG SCF can act as a promising candidate for mid-infrared laser seed source.
引用
收藏
页数:6
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共 39 条
  • [1] Up-conversion luminescence of Er3+-doped yttrium, scandium, gallium garnet at different temperatures
    Chen, XS
    Collins, J
    DiBartolo, B
    Bowlby, B
    Dinerman, B
    Weyburne, D
    [J]. JOURNAL OF LUMINESCENCE, 1997, 72-4 : 168 - 170
  • [2] Intracavity-pumped Cr2+:ZnSe laser with ultrabroad tuning range between 1880 and 3100 nm
    Demirbas, Umit
    Sennaroglu, Alphan
    [J]. OPTICS LETTERS, 2006, 31 (15) : 2293 - 2295
  • [3] LASER WEAPONS GET REAL
    Extance, Andy
    [J]. NATURE, 2015, 521 (7553) : 408 - 410
  • [4] Energy-transfer upconversion and thermal lensing in high-power end-pumped Nd:YLF laser crystals
    Hardman, PJ
    Clarkson, WA
    Friel, GJ
    Pollnau, M
    Hanna, DC
    [J]. IEEE JOURNAL OF QUANTUM ELECTRONICS, 1999, 35 (04) : 647 - 655
  • [5] Single-crystal fiber optics: a review
    Harrington, James A.
    [J]. SOLID STATE LASERS XXIII: TECHNOLOGY AND DEVICES, 2014, 8959
  • [6] 2.70 mu m CrEr: YSGG laser with high output energy and FTIR-Q-switch
    Hogele, A
    Horbe, G
    Lubatschowski, H
    Welling, H
    Ertmer, W
    [J]. OPTICS COMMUNICATIONS, 1996, 125 (1-3) : 90 - 94
  • [7] Diode End-Pumped 1.37 W Er:YSGG Continuous-Wave Laser Around 2.8-μm
    Hu, Lunzhen
    Sun, Dunlu
    Zhang, Huili
    Luo, Jianqiao
    Quan, Cong
    Han, Zhiyuan
    Dong, Kunpeng
    Chen, Yuwei
    Cheng, Maojie
    [J]. IEEE PHOTONICS TECHNOLOGY LETTERS, 2021, 33 (12) : 611 - 614
  • [8] Bulk growth and an efficient mid-IR laser of high-quality Er:YSGG crystals
    Hu, Qiangqiang
    Nie, Hongkun
    Mu, Wenxiang
    Yin, Yanru
    Zhang, Jian
    Zhang, Baitao
    He, Jingliang
    Jia, Zhitai
    Tao, Xutang
    [J]. CRYSTENGCOMM, 2019, 21 (12) : 1928 - 1933
  • [9] Crystal growth and spectral broadening of a promising Yb:CaLuxGd1-xAlO4 disordered crystal for ultrafast laser application
    Hu, Qiangqiang
    Jia, Zhitai
    Volpi, Azzurra
    Veronesi, Stefano
    Tonelli, Mauro
    Tao, Xutang
    [J]. CRYSTENGCOMM, 2017, 19 (12): : 1643 - 1647
  • [10] Germanium tin: silicon photonics toward the mid-infrared [Invited]
    Kasper, E.
    Kittler, M.
    Oehme, M.
    Arguirov, T.
    [J]. PHOTONICS RESEARCH, 2013, 1 (02) : 69 - 76
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