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非线性光学激光合束技术研究进展

崔璨 王月 王雨雷 白振旭 吕志伟

崔璨, 王月, 王雨雷, 等. 非线性光学激光合束技术研究进展[J]. 强激光与粒子束, 2023, 35: 041006. doi: 10.11884/HPLPB202335.220359
引用本文: 崔璨, 王月, 王雨雷, 等. 非线性光学激光合束技术研究进展[J]. 强激光与粒子束, 2023, 35: 041006. doi: 10.11884/HPLPB202335.220359
Cui Can, Wang Yue, Wang Yulei, et al. Research progress on nonlinear optics laser beam combining technology[J]. High Power Laser and Particle Beams, 2023, 35: 041006. doi: 10.11884/HPLPB202335.220359
Citation: Cui Can, Wang Yue, Wang Yulei, et al. Research progress on nonlinear optics laser beam combining technology[J]. High Power Laser and Particle Beams, 2023, 35: 041006. doi: 10.11884/HPLPB202335.220359

非线性光学激光合束技术研究进展

doi: 10.11884/HPLPB202335.220359
基金项目: 国家自然科学基金项目(62075056, 61927815); 天津市自然科学基金项目(20JCZDJC00430)
详细信息
    作者简介:

    崔 璨,cancui2021@hebut.edu.cn

    通讯作者:

    王雨雷,wyl@hebut.edu.cn

  • 中图分类号: TN248

Research progress on nonlinear optics laser beam combining technology

  • 摘要: 回顾了非线性光学激光合束技术的发展历程,阐述了基于光学相位共轭和基于非线性放大过程的合束思想和基本原理,梳理了重叠耦合、种子注入和布里渊四波混频增强相位锁定激光合束方式的标志性成果,总结了等离子体交叉光束能量转移、金刚石拉曼放大和液体布里渊放大激光合束技术的优势和瓶颈。面向高峰值功率、高平均功率、高重复频率激光输出的实现需求,基于布里渊放大激光合束技术具备系统结构简单、功率负载高且散热效率高的优点,提出了实现单脉冲能量100 J、脉冲宽度10 ns、重复频率10 Hz合束激光输出的可行性方案。
  • 图  1  两种基于SBS-PCM相位锁定的激光合束方式

    Figure  1.  Two kinds of SBS-PCM phase-locking laser beam combining methods

    图  2  N.G. Basov 两束垂直偏振泵浦光的相干合束示意图[31]

    Figure  2.  N.G. Basov coherent beam combining of two vertically polarized pump beams[31]

    图  3  Kumgang-4 kW相干合束激光系统光路图[39]

    Figure  3.  Diagram of Kumgang-4 kW coherent beam combining laser system[39]

    图  4  布里渊增强四波混频原理示意图[40]

    Figure  4.  Diagram of Brillouin enhanced four-wave mixing principle[40]

    图  5  布里渊增强四波混频相位共轭系统[31]

    Figure  5.  Brillouin-enhanced four-wave mixing phase-conjugating system[31]

    图  6  美国利弗莫尔实验室四路光相干合束光路示意图与输出近远场分布测量结果[42]

    Figure  6.  Schematic diagram of the four-beam optical coherent beam path with output near- and far- field distribution measurements at LLNL, USA[42]

    图  7  等离子体内Raman放大过程示意图[45]

    Figure  7.  Schematic diagram of Raman amplification process in plasma[45]

    图  8  美国利弗莫尔实验室等离子体八束激光合束实验[56]

    Figure  8.  Eight-beam laser beam combining in plasma experiment at LLNL, USA[56]

    图  9  R. K. Kirkwood等人[58]21路交叉能量转移实验示意图

    Figure  9.  Schematic diagram of the 21 cross beam energy transfer experiment by R. K. Kirkwood et al[58]

    图  10  四色前端系统光路示意图[62]

    Figure  10.  Four-color front-end system optical path diagram[62]

    图  11  澳大利亚麦考瑞大学基于拉曼放大的金刚石激光合束[66]

    Figure  11.  Raman amplification-based diamond laser beam combining at Macquarie University, Australia[66]

    图  12  主动频率补偿的非共线SBS百皮秒脉冲放大光路示意图[75]

    Figure  12.  Schematic diagram of the non-collinear SBS amplification process of hundreds-picosecond pulse with active frequency compensation[75]

    图  13  基于SBS放大激光合束技术的重复频率百焦耳激光系统设计方案[76]

    Figure  13.  Design of a repetitive-rated hundred-joule level laser system based on SBS amplification laser beam combining technology[76]

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出版历程
  • 收稿日期:  2023-03-02
  • 修回日期:  2023-03-23
  • 录用日期:  2023-03-29
  • 网络出版日期:  2023-03-30
  • 刊出日期:  2023-03-30

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