基于多纵模振荡种子源的高功率窄线宽光纤器关键技术分析及研究现状 -

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基于多纵模振荡种子源的高功率窄线宽光纤器关键技术分析及研究现状

doi:10.37188/CO.2023-0074

北京航天控制仪器研究所, 北京 100094

基金项目:国家自然科学基金(No. U20B2058)

详细信息

作者简介:
孙仕豪，1991年生于山西省。他于2013年获得了北京邮电大学电子信息科学与技术专业学士学位；2013年至2016年，在中国联通天津市分公司工作；2016年至2022年，参加了北京邮电大学和中国工程物理研究院聚变研究中心的联合培养，并于2022年获得了北京邮电大学电子科学与技术专业的博士学位；同年，在北京航天控制仪器研究所工作，研究方向为窄线宽光纤器和抗辐照光纤器
郑也，高级工程师，1989年生于黑龙江省。他于2012年获得了哈尔滨工业大学电子科学与技术专业学士学位；于2017年获得了中国科学院上海光学精密机械研究所光学工程博士学位；同年，在北京航天控制仪器研究所参加工作，研究方向包括高功率光纤器、高功率组束光纤器和窄线宽光纤器
王军龙，研究员，1975年生于吉林省。他于1998年获得了长春理工大学光电子技术专业学士学位；于2011年获得了中国运载火箭技术研究院导航、制导与控制博士学位；自2001年起，在北京航天控制仪器研究所工作，主持了多项光纤器，与材料作用机理等创新研发项目。研究方向包括高功率光纤器和光谱组束器
王学锋，研究员，1974年生于山西省。他于1997年获得了武汉测绘科技大学光技术与光电子仪器专业学士学位；于2002年获得了中国科学院上海光学精密机械研究所光学工程博士学位；已在航天领域工作了20多年，并于2013年获得中国航天基金会奖；领导了多项科学研究项目，包括高功率光纤器、特种光纤应用、光纤传感和光纤陀螺仪等

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出版历程
- 网络出版日期:2023-09-22

Analysis of key technologies and progress of high-power narrow linewidth fiber laser based on the multi-longitudinal-mode oscillator seed source

Beijing Institute of Aerospace Control Devices, Beijing 100094, China

Funds:Supported by National Natural Science Foundation of China (No. U20B2058)

More Information

Corresponding author:zhengye.no1@163.com;wjl_casc@126.com;xuefeng_wang@sina.cn

摘要

摘要:
基于多纵模振荡种子源的窄线宽光纤器具有光路简单、结构紧凑、可靠性高、成本低等特点，在实际工程应用以及在空间受限的载荷平台上有着显著优势，是高功率光谱合成的理想子束模块。受自脉冲效应的影响，多纵模振荡种子源的时域特性较差，导致放大过程中会产生较强的光谱展宽与受激拉曼散射效应。这限制了其输出功率的进一步提升并降低了其光谱纯度。本文首先介绍了4种常见的窄线宽种子源，并重点分析了多纵模振荡种子源中自脉冲效应产生的机理及抑制方法，对优化多纵模振荡种子源和放大器的关键技术进行了详细介绍，归纳总结了近几年的技术突破与研究成果，对未来的发展方向进行了展望分析。本文研究对基于多纵模振荡种子源的窄线宽器的功率提升和光谱优化提供一定思路。
- 窄线宽/
- 光纤器/
- 多纵模振荡种子源/
- 自脉冲/
- 复合腔
Abstract:
Narrow linewidth fiber lasers, which are based on an oscillator seed source with multiple longitudinal-mode, offer substantial advantages for engineering applications and space-limited platform payloads. Additionally, they are considered ideal sub-modules for high-power spectral combinations. The time domain of this type of seed is unstable due to the self-pulse effect, causing significant spectral broadening and stimulated Raman scattering effects during the amplification process. These effects limit the further improvement in output power and affect the purity of laser spectra. This paper introduces four commonly used narrow linewidth seeds. The mechanism and suppression methods of the self-pulse effect in multi-longitudinal mode oscillator seeds were analyzed. Critical technologies essential for the optimization and relevant progress of the multi-longitudinal-mode oscillator seed source and amplifier stages are discussed in detail. A future development outlook is also presented. This paper serves as a useful reference for the design of narrow linewidth fiber lasers based on the multi-longitudinal-mode oscillator seed source.
- Narrow linewidth/
- fiber laser/
- multi-longitudinal-mode oscillator seed/
- self-pulse effect/
- complex oscillator cavity

HTML全文

图 1不同窄线宽种子源示意图。（a）单频相位调制种子源；（b）超荧光光源窄带滤波种子源；（c）随机光纤器种子源；（d）多纵模振荡种子源

Figure 1.Schematic diagram of different narrow-linewidth seed source. (a) Single frequency laser seed sources; (b) narrow-band filtered seed source of superfluorescent light source, (c) random fiber laser seed source, (d) narrow-linewidth multi-longitudinal-mode oscillator seed source

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图 2不同功率和时间尺度上的自脉冲时域信号。（a）在微秒尺度上的阈值自脉冲；（b）在十纳秒尺度上的阈值自脉冲；（c）在微秒尺度上的较高功率自脉冲；（d）在十纳秒尺度上的较高功率自脉冲^[35]

Figure 2.Time-domain signals of self-pulse with different powers at different time scales. (a) Laser threshold self-pulse on the microsecond scale; (b) laser threshold self-pulse on the ten nanosecond scale; (c) laser threshold self-pulse with higher power on the microsecond scale; (d) laser threshold self-pulse with higher power on the ten nanosecond scale^[35]

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图 3不同带宽输出耦合光栅构成的振荡腔时域测试结果^[35]

Figure 3.Time-domain test results of oscillator with different OC-FBGs of different bandwidths^[35]

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图 4不同腔长震荡器在输出功率为18.25 W时的时序特性。（a）微秒尺度下的时序特性；（b）纳秒尺度下的时序特性^[35]

Figure 4.Time-domain characteristic of oscillator with different lengths when the output power is 18.25 W. (a) At microsecond scale; (b) at nanosecond scale^[35]

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图 5（a）不含F-P腔和（b）含F-P腔空间耦合F-P腔抑制自脉冲实验示意图

Figure 5.Schematic diagram of self-pulse suppression experiment (a) without and (b) with spatially coupled F-P cavity

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图 6全光纤化的复合振荡腔示意图

Figure 6.Schematic diagram of complex oscillator cavity with all-fiber configuration

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图 7基于振荡腔种子级的高功率光谱。（a）对单振荡腔种子光进行放大后的光谱；（b）对复合振荡腔种子光进行放大后的光谱^[35]

Figure 7.High power laser spectra based on different oscillator cavities. (a) Laser spectra after amplification of single oscillator cavity; (b) laser spectra after amplification of complex oscillator cavity^[35]

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图 8引入CTFBG前后1 kW窄线宽的SRS抑制情况

Figure 8.SRS suppression of 1 kW narrow line width fiber laser with and without CTFBG

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图 9（a）常规腔型种子源、（b）复合腔种子源、（c）加长复合腔种子源、（d）放大级光路图的光路示意图^[51]

Figure 9.Schematic diagrams of optical paths of (a) ordinary oscillator cavity seed source, (b) complex oscillator cavity seed source, (c) long complex oscillator cavity seed source, (d) amplifier stage^[51]

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图 10基于复合腔振荡种子源的窄线宽单级MOPA结构系统示意图^[52]

Figure 10.Schematic diagram of narrow-linewidth single stage MOPA configuration laser system based on complex cavity oscillator seed source^[52]

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图 111045 nm窄线宽光纤器光路示意图

Figure 11.Schematic diagram of optical path of narrow-linewidth fiber laser at 1045 nm

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图 123.3 kW窄线宽光纤器光路示意图

Figure 12.Schematic diagram of the optical path of a 3.3 kW narrow-linewidth fiber laser

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图 13“种子-放大级共享泵浦”结构示意图

Figure 13.Structural diagram of the “seed-amplifier sharing pump”

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图 14不同泵浦方式的线宽变化规律

Figure 14.The variation of line width under different pumping methods

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