多单管堆叠半导体激光器热分析及光纤耦合模拟仿真设计

王娇娇; 石琳琳; 马晓辉; 张贺; 李岩; 李卫岩; 徐莉

doi:doi:10.37188/cjl.20200243

发光学报, 2021, 42 (1): 104, 网络出版: 2021-04-07

多单管堆叠半导体激光器热分析及光纤耦合模拟仿真设计

Thermal Analysis and Fiber Coupling Simulation Design of Multi-single Emitters Stacked Semiconductor Laser

论文大纲

王娇娇 ^*石琳琳马晓辉张贺李岩李卫岩徐莉

作者单位

长春理工大学高功率半导体激光国家重点实验室, 吉林长春 130022

半导体激光器有限元分析散热性能光纤耦合 semiconductor laser finite element analysis ZEMAX ZEMAX heat dissipation fiber coupling

摘要

多单管合束技术是获得高输出功率密度半导体激光器的重要方法, 但其存在封装方式单一、体积大等问题, 难以满足更高功率密度和较好光束质量的需求。本文设计了一种多单管半导体激光器堆叠排布的封装结构, 通过将多个单管半导体激光器垂直封装在辅助热沉之间, 使得器件更加小型化, 在充分利用单管半导体激光器优势的同时, 既增加了单管半导体激光器的散热通道, 又实现了在体积不增加的基础上提高输出功率。通过ZEMAX软件对3个单管进行了空间合束模拟, 将光束耦合进芯径200 μm、数值孔径0.22的光纤中, 可以达到28.6 W的激光输出, 耦合效率为95%。

Abstract

Multi-single diode laser emitters combination technology is an important method to obtain semiconductor lasers with high output power density. The difficulty of simplex packaging method and large volume restricts their application of high power and high optical quality. In this paper, a packaging structure with vertically stacked arrangement of multi-single emitters diode lasers is designed by vertically encapsulating single diode laser emitters between auxiliary heat sinks, making the device more miniaturization. This method can not only increase the heat dissipation channel of the single diode laser emitters, but also realize the improvement of output power without increasing the volume. In simulation, with ZEMAX optical design software, 3 single emitters diode lasers are coupled into a fiber with core diameter of 200 μm and NA of 0.22. The simulation results of the maximum output power of 28.6 W and the coupling efficiency of 95% were obtained.

参考文献

[1] 耿素杰,王琳. 半导体激光器及其在军事领域的应用［J］. 激光与红外, 2003,33(4): 311-312.

[2] 马骁宇,王俊,刘素平. 国内大功率半导体激光器研究及应用现状［J］. 红外与激光工程, 2008,37(2): 189-194.

[3] 田锟,邹永刚,马晓辉,等. 面发射分布反馈半导体激光器［J］. 中国光学, 2016,9(1): 51-64.

[4] 韩晓俊,李正佳,朱长虹. 半导体激光器在医学上的应用［J］. 光学技术, 1998(2): 7-10.

[5] 吴华玲,郭林辉,王昭,等. 基于双管的高亮度半导体激光器光纤耦合系统设计［J］. 中国激光, 2016,43(10): 1001012-1-7.

[6] 周泽鹏. 百瓦级高亮度半导体激光器光纤耦合设计［D］. 长春: 长春理工大学, 2014.

[7] 郝明明,朱洪波,秦莉,等. 百瓦级高亮度光纤耦合半导体激光模块的研制［J］. 发光学报, 2012,33(6): 651-659.

[8] KARLSEN S R,PRICE R K,REYNOLDS M,et al.. 100-W 105-μm 0.15 NA fiber coupled laser diode module ［C］. Proceedings of SPIE 7198, High-power Diode Laser Technology and Applications Ⅶ,San Jose, 2009: 71980T-1-8.

[9] HOU L B,ZHANG H,XU L,et al.. Design of high-brightness 976 nm fiber-coupled laser diodes based on ZEMAX ［C］. Proceedings of SPIE 9521, Selected Papers from Conferences of The Photoelectronic Technology Committee of the Chinese Society of Astronautics 2014, Part Ⅰ,Nanjing, 2015: 95211F-1-8.

[10] WANG B,ZHU J. Spectral beam combining of multi-single emitters ［J］. Proceedings of SPIE 9733, High-power Diode Laser Technology and Applications ⅩⅣ,San Francisco, 2016: 97330F.

[11] 谢文君,曹银花,许商瑞,等. 基于曲面空间合束的多单管半导体激光光纤耦合［J］. 发光学报, 2018,39(9): 1280-1284.

[12] FRITSCHE H,KRUSCHKE B,KOCH R,et al.. High brightness direct diode laser with kW output power ［J］. Proceedings of SPIE 8965, High-power Diode Laser Technology and Applications Ⅻ,San Francisco, 2014: 89650G-1-7.

[13] FARMER J N,SCHULTE D E,YAN Y. Vertically displaced stack of multi-mode single emitter laser diodes: USA, 20090103580A1 ［P］. 2009-04-23.

[14] 王文,高欣,周泽鹏,等. 百瓦级多芯片半导体激光器稳态热分析［J］. 红外与激光工程, 2014,43(5): 1438-1443.

[15] 杨宏宇,刘林,舒世立,等. 大功率半导体激光器有源区温度影响因素分析［J］. 江苏科技大学学报(自然科学版), 2017,31(2): 143-147.

[16] 姜晓光,赵英杰,吴志全. 基于ANSYS半导体激光器热特性模拟与分析［J］. 长春理工大学学报(自然科学版), 2010,33(1): 41-43.

[17] 辛国锋,沈力,皮浩洋,等. 高功率半导体激光器热阻测量的实验研究［J］. 激光与光电子学进展, 2010,47(11): 112501-1-5.

[18] WU Y L,DONG Z Y,CHEN Y Q,et al.. Beam shaping for kilowatt fiber-coupled diode lasers by using one-step beam cutting-rotating of prisms ［J］. Appl. Opt., 2016,55(34): 9769-9773.

[19] 于贺,马晓辉,赵鑫,等. 基于半导体激光器堆栈的光纤耦合技术［J］. 中国激光, 2017,44(11): 1101006-1-6.

王娇娇, 石琳琳, 马晓辉, 张贺, 李岩, 李卫岩, 徐莉. 多单管堆叠半导体激光器热分析及光纤耦合模拟仿真设计[J]. 发光学报, 2021, 42(1): 104. WANG Jiao-jiao, SHI Lin-lin, MA Xiao-hui, ZHANG He, LI Yan, LI Wei-yan, XU Li. Thermal Analysis and Fiber Coupling Simulation Design of Multi-single Emitters Stacked Semiconductor Laser[J]. Chinese Journal of Luminescence, 2021, 42(1): 104.

多单管堆叠半导体激光器热分析及光纤耦合模拟仿真设计

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