Theory study on passively mode-locked Er<sup>3+</sup>-doped fluorine fiber laser

Wang Shaoqi; Deng Ying; Li Chao; Wang Fang; Zhang Yongliang; Kang Minqiang; Xue Haitao; Luo Yun; Su Jingqin; Hu Dongxia; Zheng Kuixing; Zhu Qihua

doi:10.3788/irla201645.1136004

Infrared and Laser Engineering, Volume. 45, Issue 11, 1136004(2016)

Theory study on passively mode-locked Er³⁺-doped fluorine fiber laser

Wang Shaoqi1...2,3,4,*, Deng Ying1,3, Li Chao1, Wang Fang1, Zhang Yongliang1, Kang Minqiang1, Xue Haitao1, Luo Yun1, Su Jingqin1,2,3, Hu Dongxia1,3, Zheng Kuixing1, and Zhu Qihua1,23 |Show fewer author(s)

Author Affiliations

¹[in Chinese]

²[in Chinese]

³[in Chinese]

⁴[in Chinese]

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References(14)

[1] [1] Wang Pu, Liu Jiang. Progress and prspect on ultrafast Tm-doped fiber lasers at 2 μm wavelength[J]. Chinese J Lasers, 2013, 40(6): 0601002. (in Chinese)

[2] [2] Yu Feng, Sun Chang, Gao Jing, et al. All-fiber ultra-short super-continuum generation and characters[J]. Infrared and Laser Engineering, 2014, 43(11): 3555-3558. (in Chinese)

[3] [3] Walsh B. Review of Tm and Ho materials; spectroscopy and lasers[J]. Laser Phys, 2009, 19(4): 855-866.

[4] [4] Chen Hao, Li Jianfeng, Ou Zhonghua, et al. Progress of Mid-Infrared fiber lasers[J]. Lasers & Optoelectronics Progress, 2011, 48(11): 111402. (in Chinese)

[5] [5] Zhu F, Hundertmark H, Kolomenskii A A, et al. High-power mid-infrared frequency comb source based on a femtosecond Er: fiber oscillator [J]. Opt Lett, 2011, 38(13): 2360-2362.

[6] [6] Gao Jing, Yu Feng, Kuang Hongshen, et al. High power 28 W supercontinuum fiber laser source[J]. Infrared and Laser Engineering, 2014, 43(9): 2840-2843. (in Chinese)

[7] [7] Wei C, Zhu X S, Norwood R A, et al. Passively continuous-wave mode-locked Er3+-doped ZBLAN fiber laser at 2.8 μm[J]. Opt Lett, 2012, 37(18): 3849-3851.

[8] [8] Wang P, Yang L M, Liu J. High pulse energy 2 μm femtosecond fiber laser[J]. Opt Express, 2013, 21(2): 1798-1803.

[9] [9] Liu J, Wang P. High-power passively mode-locked thulium-doped femtosecond fiber laser at 2.0 μm[J]. Chinese J Lasers, 2012, 39(9): 0902001. (in Chinese).

[10] [10] Renard W, Canat G, Bourdon P. 26 nJ picosecond solitons from thulium-doped single-mode master oscillator power fiber amplifier[J]. Opt Lett, 2012, 37(3): 377-379.

[11] [11] Haboucha A, Fortin V, Bernier M, et al. Fiber Bragg grating stabilization of a passively mode-locked 2.8 μm Er3+: fluoride glass fiber laser[J]. Opt Lett, 2014, 39(11): 3294-3297.

[12] [12] Li J F, Hudson D D, Liu Y, et al. Efficient 2.87 μm fiber laser passively switched using a semiconductor saturable absorber mirror[J]. Opt Lett, 2012, 37(18): 3747-3749.

[13] [13] Hu T, Hudson D D, Jackson S D. Stable, self-starting, passively mode-locked fiber ring laser of the 3 μm class[J]. Opt Lett, 2014, 39(7): 2133-2136.

[14] [14] Agrawal G P. Nonlinear Fiber Optics Fifth Edition[M]. London: Academic Press, 2013: 57-59.

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Wang Shaoqi, Deng Ying, Li Chao, Wang Fang, Zhang Yongliang, Kang Minqiang, Xue Haitao, Luo Yun, Su Jingqin, Hu Dongxia, Zheng Kuixing, Zhu Qihua. Theory study on passively mode-locked Er³⁺-doped fluorine fiber laser[J]. Infrared and Laser Engineering, 2016, 45(11): 1136004

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Paper Information

Category: 高能激光技术

Received: Mar. 10, 2016

Accepted: Apr. 5, 2016

Published Online: Jan. 20, 2017

The Author Email: Shaoqi Wang (wangshq_caep@163.com)

DOI:10.3788/irla201645.1136004

Topics

laser devices and laser physics

Lasers and Laser Optics

Laser physics

laser manufacturing

Instrumentation, Measurement and Metrology

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