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高功率掺镱光纤激光器的辐照影响分析及研究进展

郑也 马梓洋 朱嘉婧 于淼 李思源 张琳 王军龙 王学锋

郑也, 马梓洋, 朱嘉婧, 等. 高功率掺镱光纤激光器的辐照影响分析及研究进展[J]. 强激光与粒子束, 2022, 34: 041003. doi: 10.11884/HPLPB202234.210414
引用本文: 郑也, 马梓洋, 朱嘉婧, 等. 高功率掺镱光纤激光器的辐照影响分析及研究进展[J]. 强激光与粒子束, 2022, 34: 041003. doi: 10.11884/HPLPB202234.210414
Zheng Ye, Ma Ziyang, Zhu Jiajing, et al. Influence of space radiation on properties of high power Yb-doped fiber lasers and their recent progress[J]. High Power Laser and Particle Beams, 2022, 34: 041003. doi: 10.11884/HPLPB202234.210414
Citation: Zheng Ye, Ma Ziyang, Zhu Jiajing, et al. Influence of space radiation on properties of high power Yb-doped fiber lasers and their recent progress[J]. High Power Laser and Particle Beams, 2022, 34: 041003. doi: 10.11884/HPLPB202234.210414

高功率掺镱光纤激光器的辐照影响分析及研究进展

doi: 10.11884/HPLPB202234.210414
基金项目: 国家自然科学基金企业创新发展联合基金项目(U20B2058)
详细信息
    作者简介:

    郑 也,zhengye.no1@163.com

    通讯作者:

    王军龙,wjl_casc@126.com

    王学锋,xuefeng_wang@sina.com

  • 中图分类号: TN248.1

Influence of space radiation on properties of high power Yb-doped fiber lasers and their recent progress

  • 摘要:

    高功率掺镱光纤激光器在空间环境中的应用日益增多,但掺镱光纤材料在空间辐照条件下会产生色心效应,导致损耗增加,影响光纤器件以及激光器整机的性能,从而给高功率光纤激光器在空间环境的长期稳定工作带来隐患。从空间辐照对高功率光纤激光器性能的影响机理、抑制方法和研究进展等3个方面进行介绍。首先介绍了空间辐照对高功率掺镱光纤激光器中关键光学器件、放大级热负载、非线性效应等方面的影响分析,其次介绍了抑制辐照效应的典型方法及其在高功率掺镱光纤激光器中的可行性分析,最后介绍了国内外典型的高功率掺镱光纤激光器的辐照影响及抑制的研究成果,并展望了未来发展趋势。

  • 图  1  基于MOPA结构的高功率掺镱光纤激光器组成示意图

    Figure  1.  Construction of high power Yb-doped fiber laser based on MOPA structure

    图  2  Yb3+掺杂光纤辐致色心形成模型

    Figure  2.  The model of radiation-induced color center of the Yb3+-doped fiber

    图  3  载氢处理抑制光子暗化空穴相关色心的原理示意图

    Figure  3.  Illustration of suppressing the hole-related color center by H2 loading treatment

    图  4  (a)光纤长度及(b)泵浦结构对EDFA 辐照性能的影响;(c)采用优化的光纤长度和泵浦结构与非优化参数的EDFA辐照性能对比

    Figure  4.  Influence of (a) doped fiber length and (b) pump structure on the EDFA’s radiation properties; (c) comparison of the EDFA’s radiation properties with and without the optimized parameters

    图  5  不同掺杂光纤的增益随辐照总剂量的变化规律

    Figure  5.  Variation of gain versus total radiation dose of three different doping fibers

    图  6  不同辐照剂量、不同系统参数下放大器性能变化规律

    Figure  6.  Variation trend of the amplifier under different dose and different system parameters

    图  7  915 nm与976 nm泵浦下(a)输出激光功率及(b)单位长度光纤的辐致损耗随辐照剂量变化规律

    Figure  7.  (a) Output power and (b) irradiation loss vs irradiation dose under 915 nm and 976 nm pump

    图  8  辐照前后(a)光纤合束器耦合效率与(b)包层光剥离器剥离度变化情况

    Figure  8.  Properties variation of (a) combiner and (b) cladding pump stripper before and after radiation

    图  9  不同辐照剂量条件下的激光斜率效率

    Figure  9.  Slope efficiency under different total radiation dose

    图  10  原始光纤、γ辐照光纤及532 nm漂白后光纤的输出功率和标准偏差随泵浦功率变化关系

    Figure  10.  Output power and STD versus pump power of pristine, γ irradiated and 532 nm bleached fibers

    图  11  不同泵浦时光纤振荡器不同信号波长的输出功率

    Figure  11.  Output power of the fiber laser at different wavelength under diffevent pump

    图  12  (a)TMI随辐照剂量变化关系以及(b)不同辐照剂量下输出功率分布和TMI区域

    Figure  12.  (a) Variation of TMI versus radiation dose and (b) the output power profile and TMI area under different radiation dose

    图  13  掺铈光纤与商用光纤不同条件下随辐照总剂量变化规律

    Figure  13.  Comparison of properties under different radiation dose between Ce doped fiber and commercial fiber

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  • 收稿日期:  2021-09-20
  • 修回日期:  2021-12-18
  • 网络出版日期:  2022-01-05
  • 刊出日期:  2022-03-19

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