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    Journals >Infrared and Laser Engineering >Volume 51 >Issue 6 >Page 20220133 > Article
    • Infrared and Laser Engineering
    • Vol. 51, Issue 6, 20220133 (2022)
    Research progress of single-frequency fiber laser based on Re: YAG-SiO2 fiber (Invited)
    Zhenshuai Wei1, Yongyao Xie2, Xianbin Shao2, Jundu Liu1, Wei Zhao2, Xian Zhao1, Xingyu Zhang1、2, Zhigang Zhao1、2, Zhenhua Cong1、2, and Zhaojun Liu1、2
    Author Affiliations
  • 1Key Laboratory of Laser & Infrared System (Shandong University), Ministry of Education, Qingdao 266237, China
  • 2Shandong Provincial Key Laboratory of Laser Technology and Application, School of Information Science and Engineering,Shandong University, Qingdao 266237, China
    • show less
    DOI: 10.3788/IRLA20220133 Cite this Article
    Zhenshuai Wei, Yongyao Xie, Xianbin Shao, Jundu Liu, Wei Zhao, Xian Zhao, Xingyu Zhang, Zhigang Zhao, Zhenhua Cong, Zhaojun Liu. Research progress of single-frequency fiber laser based on Re: YAG-SiO2 fiber (Invited)[J]. Infrared and Laser Engineering, 2022, 51(6): 20220133 Copy Citation Text show less
    References

    [1] N Chiodo, K Djerroud, O Acef, et al. Lasers for coherent optical satellite links with large dynamics. Applied Optics, 52, 7342-7351(2013).

    [2] T Chen, W Kong, H Liu, et al. Frequency-stepped pulse train generation in an amplified frequency-shifted loop for oxygen A-band spectroscopy. Optics Express, 26, 34753-34762(2018).

    [3] B P Abbott, R Abbott, T D Abbott, et al. GW151226: Observation of gravitational waves from a 22-solar-mass binary black hole coalescence. Physical Review Letters, 116, 241103(2016).

    [4] C Abari, Pedersen A Tegtmeier, E Dellwik, et al. Performance evaluation of an all-fiber image-reject homodyne coherent Doppler wind lidar. Atmospheric Measurement Techniques, 8, 4145-4153(2015).

    [5] Cao C Y. Study on key techniques of high perfmance fiberoptics hyhone array based on ultraremotely optical transmission caded amplifiers[D]. Changsha: National University of Defense Technology, 2013. (in Chinese)

    [6] Y Cheng, J T Kringlebotn, W H Loh, et al. Stable single-frequency traveling-wave fiber loop laser with integral saturable-absorber-based tracking narrow- band filter. Optics Letters, 20, 875-877(1995).

    [7] N Park, J Dawson, K Vahala, et al. All fiber, low threshold, widely tunable single-frequency, erbium-doped fiber ring laser with a tandem fiber Fabry-Perot filter. Applied Physics Letters, 59, 2369-2371(1991).

    [8] J W Chen, Y Zhao, Y N Zhu, et al. Narrow line-width ytterbium-doped fiber ring laser based on saturated absorber. IEEE Photonics Technology Letters, 29, 439-441(2017).

    [9] X X Ma, B L Lu, K L Wang, . Tunable broadband single-frequency narrow-linewidth fiber laser. Acta Optica Sinica, 39, 0114001(2019).

    [10] X Wang, F P Yan, W G Han. Single longitudinal mode narrow linewidth thulium-doped fiber laser with special subring cavity. Chinese Journal of Lasers, 46, 0901001(2019).

    [11] J T Kringlebotn, J L Archambault, L Reekie, et al. Er3+: Yb3+-codoped fiber distributed-feedback laser. Optics Letters, 19, 2101-2103(1994).

    [12] L Dong, W H Loh, J E Caplen, et al. Efficient single- frequency fiber lasers with novel photosensitive Er/Yb optical fibers. Optics Letters, 22, 694-696(1997).

    [13] W Fan, B Chen, X C Li, et al. Stress-induced single polarization DFB fiber lasers. Optics Communications, 204, 157-161(2002).

    [14] G A Ball, W W Morey. Standing-wave monomode erbium fiber laser. IEEE Photonics Technology Letters, 3, 613-615(1991).

    [15] J L Syzskind, V Mizrahi, D J Digiovanni, et al. Short single frequency erbium-doped fibre laser. Electronics Letters, 28, 1385-1387(1992).

    [16] J T Kringlebotn, P R Morkel, L Reekie, et al. Efficient diode-pumped single-frequency erbium: ytterbium fiber laser. IEEE Photonics Technology Letters, 5, 1162-1164(1993).

    [17] G A Cranch, M A Englund, C K Kirkendall, et al. Intensity noise characteristics of erbium-doped distributed-feedback fiber lasers. IEEE Journal of Quantum Electronics, 39, 1579-1587(2004).

    [18] S Loranger, V Korpov, G W Shinn, et al. Single-frequency low-threshold linearly polarized DFB Raman fiber lasers. Optics Letters, 42, 3864-3867(2017).

    [19] C Spiegelberg, J Geng, Y Hu, et al. Low-noise narrow-linewidth fiber laser at 1550 nm (June 2003). Journal of Lightwave Technology, 22, 57-62(2004).

    [20] Q Fang, Y Xu, S J Fu, et al. Single-frequency distributed Bragg reflector Nd doped silica fiber laser at 930 nm. Optics Letters, 41, 1829-1832(2016).

    [21] C S Yang, X Cen, S H Xu, . Research progress of single-frequency fiber laser(Invited). Acta Optica Sinica, 41, 0114002(2021).

    [22] T Delevaque, T Georges, M Monerie, et al. Modeling of pair-induced quenching in erbium-doped silicate fibers. IEEE Photonics Technology Letters, 5, 73-75(1993).

    [23] Y M Zhang, G Q Qian, X S Xiao, et al. The preparation of Yttrium Aluminosilicate (YAS) glass fiber with heavy doping of Tm3+ from Polycrystalline YAG ceramics. Journal of the American Ceramic Society, 101, 4627-4633(2018).

    [24] Y Y Xie, Z J Liu, Z H Cong, et al. All-fiber-integrated Yb: YAG-derived silica fiber laser generating 6 W output power. Optics Express, 27, 3791-3798(2019).

    [25] Y Wan, J X Wen, Y H Dong, et al. An exceeding 50% slope efficiency DBR fiber laser based on Yb-doped crystal-derived silica fiber with high gain per unit length. Optics Express, 28, 23771-23783(2020).

    [26] G Q Qian, W L Wang, G W Tang, et al. Tm: YAG ceramic derived multimaterial fiber with high gain per unit length for all-fiber mode-locked fiber laser applications. Optics Letters, 45, 1047-1050(2020).

    [27] G W Tang, G Q Qian, W Lin, et al. Broadband 2 μm amplified spontaneous emission of Ho/Cr/Tm: YAG crystal derived all-glass fibers for mode-locked fiber laser applications. Optics Letters, 44, 3290-3293(2019).

    [28] Y C Huang, Y K Lu, J C Chen, et al. Broadband emission from Cr-doped fibers fabricated by drawing tower. Optics Express, 14, 8492-8497(2006).

    [29] J Ballato, T Hawkins, P Foy, et al. On the fabrication of all-glass optical fibers from crystals. Journal of Applied Physics, 105, 53110(2009).

    [30] P Dragic, P Law, J Ballato, et al. Brillouin spectroscopy of YAG-derived optical fibers. Optics Express, 18, 10055-10067(2010).

    [31] J Ballato, P D Dragic. Characterisation of Raman gain spectra in Yb: YAG-derived optical fibres. Electronics Letters, 49, 895-896(2013).

    [32] P D Dragic, J Ballato, T Hawkins, et al. Feasibility study of Yb: YAG-derived silicate fibers with large Yb content as gain media. Optical Materials, 34, 1294-1298(2012).

    [33] J H Geng, Q Wang, T Luo, et al. Single-frequency narrow-linewidth Tm-doped fiber laser using silicate glass fiber. Optics Letters, 34, 3493-3495(2009).

    [34] Y M Zhang, G Q Qian, X S Xiao, et al. A yttrium aluminosilicate glass fiber with graded refractive index fabricated by melt-in-tube method. Journal of the American Ceramic Society, 101, 1616-1622(2017).

    [35] Y M Zhang, Y Sun, J X Wen, et al. Investigation on the formation and regulation of yttrium aluminosilicate fiber driven by spontaneous element migration. Ceramics International, 45, 19182-19188(2019).

    [36] S P Zheng, J Li, C L Yu, et al. Preparation and characterizations of Nd: YAG ceramic derived silica fibers drawn by post-feeding molten core approach. Optics Express, 24, 24248(2016).

    [37] S P Zheng, J Li, C L Yu, et al. Preparation and characterizations of Yb: YAG-derived silica fibers drawn by on-line feeding molten core approach. Ceramics International, 43, 5837-5841(2017).

    [38] C Z Li, Z X Jia, Z H Cong, et al. Gain characteristics of ytterbium-doped SiO2-Al2O3-Y2O3 fibers. Laser Physics, 29, 55804(2019).

    [39] Yongyao Xie, Zhenhua Cong, Zhigang Zhao, et al. Preparation of Er:YAG crystal-derived all-glass silica fibers for a 1550-nm single-frequency laser. Journal of Lightwave Technology, 39, 4769-4775(2021).

    [40] M E Fermann, I Hartl. Ultrafast fibre lasers. Nature Photonics, 7, 868-874(2013).

    [41] D J Richardson, J Nilsson, W A Clarkson. High power fiber lasers: current status and future perspectives(Invited). Journal of the Optical Society of America B, 27, B63-B92(2010).

    [42] B Leconte, H Gilles, T Robin, et al. 7.5 W blue light generation at 452 nm by internal frequency doubling of a continuous-wave Nd-doped fiber laser. Optics Express, 26, 10000-10006(2018).

    [43] M Bode, I Freitag, A Tünnermann, et al. Frequency-tunable 500-mW continuous-wave all-solid-state single-frequency source in the blue spectral region. Optics Letters, 22, 1220-1222(1997).

    [44] X S Zhu, W Shi, J Zong, et al. 976 nm single-frequency distributed Bragg reflector fiber laser. Optics Letters, 37, 4167-4169(2012).

    [45] A Bouchier, G Lucasleclin, P Georges, et al. Frequency doubling of an efficient continuous wave single-mode Yb-doped fiber laser at 978 nm in a periodically-poled MgO: LiNbO3 waveguide. Optics Express, 13, 6974-6979(2005).

    [46] W Shi, Q Fang, X S Zhu, et al. Fiber lasers and their applications(Invited). Applied Optics, 53, 6554-6568(2014).

    [47] Zhang Y M, Qiu J Q. Yttrium aluminosilicate (YAS) fiber with heavily doped of Nd f single frequency laser[C]Asia Communications Photonics Conference(ACP), 2018.

    [48] Shao X B. Preparation, acterization single frequency laser technology of Nd: YAG crystal derived fiber[D]. Jinan: Shong University, 2021. (in Chinese)

    [49] Y F Wang, Y M Zhang, J K Cao, et al. 915 nm all-fiber laser based on novel Nd-doped high alumina and yttria glass @ silica glass hybrid fiber for the pure blue fiber laser. Optics Letters, 44, 2153-2156(2019).

    [50] X B Shao, X H Chen, Z H Cong, . Single-frequency Nd: YAG crystal-derived fiber laser at 915 nm. Acta Optica Sinica, 41, 2206001(2021).

    [51] Ma X Y, Study on luminescence laser acteristics of ytterbium doped fiber[D]. Wuhan: Huazhong University of Science Technology, 2019. (in Chinese)

    [52] Zhou G D. Preparation study of highly Yb3+doped doubleclad phosphate fiber[D]. Guangzhou: South China University of Technology, 2019. (in Chinese)

    [53] Huang J. Investigation of singlefrequency distributed Bragg reflect fiber laser with highly Ybdoped silica fiber[D]. Xi''an: Nthwest University, 2017. (in Chinese)

    [54] Xie Y Y. Studies of singlefrequency laser based on YAG crystalderived silica[D]. Jinan: Shong University, 2021. (in Chinese)

    [55] Y M Zhang, W W Wang, J Li, et al. Multi-component yttrium aluminosilicate (YAS) fiber prepared by melt-in-tube method for stable single-frequency laser. Journal of the American Ceramic Society, 102, 2551-2557(2019).

    [56] Z J Liu, Y Y Xie, Z H Cong, et al. 110  mW single-frequency Yb: YAG crystal-derived silica fiber laser at 1064  nm. Optics Letters, 44, 4307-4310(2019).

    [57] Jiang M Y. Design research of single frequency laser based on Yb: YAG crystal derived fiber[D]. Jinan: Shong University, 2021. (in Chinese)

    [58] Y Y Xie, Z H Cong, Z G Zhao, et al. Linearly polarized single-frequency fiber laser based on the Yb: YAG-crystal derived silica fiber. Applied Optics, 59, 9931-9936(2020).

    [59] X B Gao, Z H Cong, Z J Zhao, et al. Single-frequency kHz-linewidth 1070 nm laser based on Yb: YAG derived silica fiber. IEEE Photonics Technology Letters, 32, 895-898(2020).

    [60] Y Y Xie, Z H Cong, Z G Zhao, . A 976 nm single-frequency laser based on the Yb: YAG crystal-derived fiber. Chinese Journal of Lasers, 48, 1201010(2021).

    [61] Y Wan, J X Wen, C Jiang, et al. Over 255 mW single-frequency fiber laser with high slope efficiency and power stability based on an ultrashort Yb-doped crystal-derived silica fiber. Photonics Research, 9, 649-656(2021).

    [62] Y Wan, J X Wen, C Jiang, et al. Over 100 mW stable low-noise single-frequency ring-cavity fiber laser based on a saturable absorber of Bi/Er/Yb co-doped silica fiber. Journal of Lightwave Technology, 40, 805-812(2022).

    [63] F Qi, B L Zheng, J Yang, et al. Fabrication of yttrium aluminosilicate fibers with high Yb3+ doping from Yb: YAG ceramic nanopowders and its application in single-frequency fiber lasers. Optical Materials Express, 12, 876-884(2022).

    [64] S Ishii, K Mizutani, H Fukuoka, et al. Coherent 2 μm differential absorption and wind lidar with conductively cooled laser and two-axis scanning device. Applied Optics, 49, 1809-1817(2010).

    [65] Engin D, Chuang T, Stm M. Compact, highly efficient, athermal, 25 W, 2051 nm Tmfiber based MOPA f CO2 tracegas laser space transmitter[C]Proceedings of SPIE LASE, 2017, 10083: 1008325.

    [66] Z Zhang, A J Boyland, J K Sahu, et al. High-power single-frequency thulium-doped fiber DBR laser at 1943 nm. IEEE Photonics Technology Letters, 23, 417-419(2011).

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    Zhenshuai Wei, Yongyao Xie, Xianbin Shao, Jundu Liu, Wei Zhao, Xian Zhao, Xingyu Zhang, Zhigang Zhao, Zhenhua Cong, Zhaojun Liu. Research progress of single-frequency fiber laser based on Re: YAG-SiO2 fiber (Invited)[J]. Infrared and Laser Engineering, 2022, 51(6): 20220133
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