激光二极管直接后向泵浦的高光束质量万瓦光纤激光器

文榆钧; 王鹏; 奚小明; 张汉伟; 黄良金; 杨欢; 闫志平; 杨保来; 史尘; 潘志勇; 王小林; 王泽锋; 许晓军

doi:10.7498/aps.71.20221433

摘要

高功率高光束质量光纤激光器在工业生产中得到了广泛应用, 但其受到光纤中非线性效应等现象的制约, 进一步功率提升严重受阻. 本文基于大模场低数值孔径增益光纤搭建了激光二极管直接泵浦的全光纤激光放大器. 通过改变增益光纤的弯曲直径, 有效地提升了动态模式不稳定阈值, 实现了最高功率10.53 kW, 光光转换效率74.04%, 光束质量因子

$M^2 \sim 2.88$ 的激光输出. 研究表明, 在少模光纤激光放大器中, 提升输出功率与改善光束质量的方法相互制约. 不考虑光束质量时激光器可以较为简单的获得万瓦乃至更高功率输出; 但是在提升功率的同时保持光束质量不退化是一件充满挑战且难度极大的工作.

关键词:

Fiber lasers have been widely used in the industrial and scientific fields due to their advantages of high conversion efficiency, simple thermal management, and consistent stability. High brightness and high-power fiber lasers are affected by stimulated Raman scattering and transverse mode instability, which limits the power scaling of fiber lasers. Therefore, there are only a few researches achieving a 10 kW-level fiber laser system by laser diode direct pumping or tandem pumping. In this work, we demonstrate an all-fiber laser amplifier based on home-made low numerical aperture (NA) fiber pumped by 976 nm laser diodes. When the signal light is input to the gain fiber with a minimum bending diameter of 12 cm, the beam quality factor M² is about 1.72. The onset of transverse mode instability (TMI) is observed at 2467 W output power, accompanied by beam quality degradation. In order to suppress the onset of TMI, the minimum bending diameter of the gain fiber is changed from 12 cm to 20 cm. And the signal light is input into the gain fiber with a bending diameter of 28 cm. Benefiting from this operation, the fiber laser amplifier achieves maximum output power of 10.53 kW with an optical-to-optical efficiency of 74.04%, and there is no TMI onset observed. However, increasing bending diameter inevitably leads the beam quality to degrade. At the maximum output power, the beam quality factor M² is 2.88. To the best of our knowledge, this is the highest optical-to-optical efficiency and the best beam quality in 10 kW-level laser diodes pumping fiber lasers. Generally, it is believed that reducing bending diameter can suppress TMI by increasing high-order mode loss. However, this rule is not applicable to few-mode fiber lasers. A larger bending diameter leads more high-order modes to be contained in the signal light instead of leaking into the cladding area. Thus, a higher output and poor beam quality are obtained. Also, it is believed that tightly coiled fiber can make mode coupling easier and trigger off TMI, which results in a positive correlation between the TMI threshold and bending diameter. Low NA fibers are very sensitive to bending, and reducing the bend diameter to control the beam quality will result in lower efficiency and a lower TMI threshold. Therefore, although producing a 10 kW-level fiber laser is simple, maintaining good beam quality in the power scaling process is still a challenge. The results of this study will be a valuable reference for high power fiber laser design.

Keywords:

PACS:

作者及机构信息

1.
国防科技大学前沿交叉学科学院, 长沙　410073

2.
国防科技大学, 南湖之光实验室, 长沙　410073

3.
脉冲功率激光技术国家重点实验室, 长沙　410073

通信作者: 王小林, chinaphotonics@163.com ; 王泽锋, zefengwang_nudt@163.com ;

基金项目: 国家自然科学基金青年科学基金(批准号: 62005315)和长沙市杰出创新青年培养计划(批准号: kq2106008)资助的课题.

Authors and contacts

1.
College of Advanced Interdisciplinary Studies, National University of Defense Technology, Changsha 410073, China

2.
Nanhu Laser Laboratory, National University of Defense Technology, Changsha 410073, China

3.
State Key Laboratory of Pulsed Power Laser Technology, Changsha 410073, China

Corresponding author: Wang Xiao-Lin, chinaphotonics@163.com ; Wang Ze-Feng, zefengwang_nudt@163.com ;

Funds: Project supported by the National Natural Science Foundation of China (Grant No. 62005315) and the Training Program for Excellent Young Innovations of Changsha, China (Grant No. kq2106008).

文章全文

参考文献

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图 1 放大器实验结构图　(a)放大器实验结构; (b) 高模式损耗实验YDF弯曲设置; (c) 低模式损耗实验YDF弯曲设置

Fig. 1. Schematic diagram of fiber laser amplifier: (a) Structure of fiber laser amplifier; (b) bending setup of high model loss experiment; (c) bending setup of low model loss experiment.

下载: 全尺寸图片幻灯片

图 2 弯曲损耗随弯曲直径的分布

Fig. 2. Bending loss distribution versus bending diameters.

下载: 全尺寸图片幻灯片

图 3 小弯曲直径时光纤激光放大器输出特性　(a)输出功率与光光转换效率随泵浦功率的变化以及最高输出时光斑形态(插图); (b) 2543 W时输出光谱

Fig. 3. Output characteristics of fiber laser amplifier at small bending diameter: (a) Output power and optical-to-optical efficiency versus pump power; the inset is beam profile at the highest output; (b) output spectrum at 2543 W.

下载: 全尺寸图片幻灯片

图 4 不同功率下时域信号与对应频谱

Fig. 4. Time domain signal and corresponding spectrum under different output.

下载: 全尺寸图片幻灯片

图 5 大弯曲直径时光纤激光放大器输出特性　(a) 输出功率与光光转换效率随泵浦功率的变化; (b) 10530 W时输出光谱; (c) 10530 W时域信号与对应频谱; (d) 10530 W时的光束质量(D4σ表示光束强度轮廓横向能量分布的四倍标准差)

Fig. 5. Output characteristics of fiber laser amplifier at big bending diameter: (a) Output power and optical-to-optical efficiency versus pump power; (b) output spectrum at 10530 W; (c) time domain signal and corresponding spectrum at 10530 W; (d) beam quality at 10530 W.

下载: 全尺寸图片幻灯片

map

[1]	顾波 2020 金属加工(热加工) 10 37 Gu B 2020 Mach. Metal Forming 10 37
[2]	Zervas M N, Codemard C A 2014 IEEE J. Sel. Top. Quantum Electron. 20 219 Google Scholar
[3]	Richardson D J, Nilsson J, Clarkson W A 2010 J. Opt. Soc. Amer. B 27 B63 Google Scholar
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[7]	Shiner B 2013 CLEO: Science and Innovations San Jose, USA, June 9–13, 2013 pAF2J.1
[8]	张春, 谢亮华, 楚秋慧, 刘玙, 黄珊, 宋华青, 吴文杰, 冯曦, 李敏, 沈本剑, 李昊坤, 陶汝茂, 许立新, 王建军 2022 强激光与粒子束 34 126 Zhang C, Xie L H, Chu Q H, Liu Y, Huang S, Song H Q, Wu W J, Feng X, Li M, Shen B J, Li H K, Tao R M, Xu L X, Wang J J 2022 High Power Laser and Part. Beams 34 126
[9]	Yang B L, Wang P, Zhang H W, Xi X M, Shi C, Wang X L, Xu X J 2021 Opt. Express 29 26366 Google Scholar
[10]	Stihler C, Jauregui C, Tunnermann A, Limpert J 2019 Conference on Lasers and Electro-Optics Europe & European Quantum Electronics Conference (CLEO/Europe-EQEC) Munich, Germany, June 23–27, 2019 pp1-1
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[12]	Wan Y C, Yang B L, Wang P, Xi X M, Zhang H W, Wang X L 2021 J. Mod. Optic. 68 967 Google Scholar
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[17]	林傲祥, 湛欢, 彭昆, 王小龙, 倪力, 王瑜英, 李雨薇, 刘爽, 孙仕豪, 姜佳丽, 唐选, 刘玙, 姜蕾, 俞娟, 王建军, 景峰 2018 强激光与粒子束 30 7 Google Scholar Lin A X, Zhan H, Peng K, Wang X L, Ni L, Wang Y Y, Li Y W, Liu S, Sun S H, Jiang J L, Tang X, Liu Y, Jiang L, Yu J, Wang J J, Jin F 2018 High Power Laser Part. Beams 30 7 Google Scholar
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[20]	李峰云, 黎玥, 宋华青, 衣永青, 楚秋慧, 张昊宇, 黄珊, 郭超, 舒强, 颜冬林, 陶汝茂, 黄智蒙, 庞璐, 沈一泽, 史仪, 高聪, 刘念, 贺红磊, 李雨薇, 刘玙, 吴文杰, 王旗华, 温静, 汪卓, 林宏奂, 王建军, 景峰 2021 中国激光 48 192 Google Scholar Li F Y, Li Y, Song H Q, Yi Y Q, Chu Q H, Zhang H Y, Huang S, Guo C, Shu Q, Yan D L, Tao R M, Huang Z M, Pang L, Shen Y Z, Shi Y, Gao C, Liu N, He H L, Li Y W, Liu Y, Wu W J, Wang Q H, Wen J, Wang Z, Lin H H, Wang J J, Jin F 2021 Chin. J. Lasers 48 192 Google Scholar
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[23]	衣永青, 刘君, 沈一泽, 李峰云, 韩志辉, 杨鹏, 庞璐, 林宏奂, 王建军 2022 中国激光 49 97 Yi Y Q, Liu J, Shen Y Z, Li F Y, Han Z H, Yang P, Pang L, Lin H H, Wang J J 2022 Chin. J. Lasers 49 97
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