高功率、高效率808nm半导体激光器阵列

王贞福; 杨国文; 吴建耀; 宋克昌; 李秀山; 宋云菲

doi:10.7498/aps.65.164203

摘要

通过设计高效率808 nm非对称宽波导外延结构，减少P型波导层和包层的自由载流子光吸收，实现腔内光吸收损耗为0.63 cm -1. 制备的808 nm半导体激光器阵列在室温25 ℃下，实现驱动电流135 A，工作电压1.76 V，连续输出功率大于150 W，斜率效率高达1.25 W/A，中心波长809.3 nm，器件最高电光转换效率为65.5%，这是目前国内报道的808 nm半导体激光器阵列的最高电光转换效率，达到国际同类器件最好水平.

关键词:

Abstract

High-power, high-efficiency 808 nm laser diode arrays for pumping solid-state lasers have been widely used in industrial, scientific, medical and biological applications. The tendency of development of 808 nm laser diode pumping with high power, high efficiency and long lifetime is well-known. Diode-pumped solid-state system with high-efficiency laser diode array has many advantages such as compact volume, lower weight and energy saving. Currently, commercial 808 nm diode laser arrays with lower power conversion efficiency of about 50%-55%, due to the optical absorption losses for GaAs-based epitaxial materials, have been reported. In order to reduce series resistance and thermal resistance, heavily doped p-type waveguide and cladding layers are employed. However, the absorption loss on the free carriers in heavily doped p-type layers is dominant, leading to a lower power conversion efficiency. In order to achieve a high efficiency, the following requirements must be considered: improving the internal quantum efficiency by reducing the carrier leakage and increasing the electron injection efficiency; minimizing the voltage drop by optimizing the operating voltage; reducing the series resistance and thermal resistance of device; minimizing the internal loss including free-carrier absorption loss and scattering loss by designing optimized waveguide and cladding structure. In this paper, optimizing the epitaxial structure and fabricating technologies are demonstrated to achieve the high efficiency and high power. The asymmetric broad waveguide epitaxial structure with lower absorption loss in p-type waveguide and cladding layer is designed in order to achieve the above goals. The high-efficiency epitaxial structure is optimized including the thickness, doping and composition for each layer structure. The strained quantum well diode laser with lower transparency current and higher differential is of benefit to achieving the high power. A novel asymmetric broad waveguide structure is designed by optimizing the waveguide thickness and component of p-waveguide so as to reduce carrier absorption loss, the optical absorption loss in this epitaxial structure is achieved to be as low as 0.63 cm-1. The wafer is grown by metalorganic chemical vapor deposition on an n-GaAs substrate. The optimized growth conditions and substrates orientation are extensively studied to improve the crystal quality and reduce the internal loss and defects. The wafer is processed using standard procedures. For the fabricated 1-cm laser diode array mounted on P-side down on copper microchannel cooled heatsink, the device shows an output power of 150 W under an operating current of 135 A with an emitting wavelength of 809 nm, an operating voltage of 1.76 V, a slope efficiency of as high as 1.25 W/A, and maximum power conversion efficiency of as high as 65.5%, which is the highest level of 808 nm diode laser array with an output power of 150 W.

Keywords:

作者及机构信息

1.
中国科学院西安光学精密机械研究所, 瞬态光学与光子技术国家重点实验室, 陕西 710119;

2.
西安立芯光电科技有限公司, 陕西 710077

通信作者: 杨国文, yangguowen@opt.ac.cn

基金项目: 国家自然科学基金（批准号：61504167）和中国科学院百人计划（批准号：Y429941233）资助的课题.

Authors and contacts

1.
Xi’an Institute of Optics and Precision Mechanics, Chinese Academy of Sciences, Shaanxi 710119, China;

2.
Xi’an Lumcore Optoelectronics Technologies Co., Ltd, Shaanxi 710077, China

Corresponding author: Yang Guo-Wen, yangguowen@opt.ac.cn

Funds: Project supported by the National Science Foundation of China (Grant No. 61504167) and the 100 Talents Project of Chinese Axademy of Sciences, China (Grant No. Y429941233).

参考文献

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[2]	Chen H P, Cao J S, Guo S X 2013 Acta Phys. Sin. 62 104209 (in Chinese) [陈海鹏, 曹军胜, 郭树旭 2013 物理学报 62 104209]
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[5]	Yamagata Y, Yamada Y, Muto M, Sato S, Nogawa R, Sakamoto A, Yamaguchi M 2015 Proc. SPIE 9348 93480F
[6]	Pietrzak A, Huelsewede R, Zorn M, Hirsekorn O, Sebastian J, Meusel J, Bluemel V, Hennig P 2014 Proc. SPIE 8965 89650T
[7]	Crump P, Erbert G, Wenzel H, Frevert C, Schultz C M, Hasler K H, Staske R, Sumpf B, Maaßdorf A, Bugge F, Knigge S, Member, Trankle G 2013 IEEE J. Sel. Top. Quant. Electron. 19 1501211
[8]	Lauer C, König H, Grönninger G, Hein S, Alvaro G I, Furitsch M, Maric J, Kissel H, Wolf P, Biesenbach J, Strauß U 2012 Proc. SPIE 8241 824111
[9]	Cao C S, Fan L, Ai I, Li J, Caliva B, Zeng L F, Thiagarajan P, McElhinney M 2010 Proc. SPIE 7583 75830L
[10]	Hlsewede R, Schulze H, Sebastian J, Schröder D, Meusel J, Hennig P 2007 Proc. SPIE 6456 645607
[11]	Peters M, Rossin V, Everett M, Zucker E, Power H 2007 Proc. SPIE 6456 64560G
[12]	Crump P A, Crum T R, DeVito M, Farmer J, Grimshaw M, Huang Z, Igl S A, Macomber S, Thiagarajan P, Wise D 2004 Proc. SPIE 5336 144
[13]	Wang J, Smith B, Xie X M, Wang X Q, Burnham G T 1999 Appl. Phys. Lett. 74 1525
[14]	Zhong L, Wang J, Feng X M, Wang Y G, Wang C L, Han L, Chong F, Liu S P, Ma X Y 2007 Chinese J. Lasers 34 1038 (in Chinese) [仲莉, 王俊, 冯小明, 王勇刚, 王翠鸾, 韩琳, 崇锋, 刘素平, 马骁宇 2007 中国激光 34 1038]
[15]	Yang H W, Huang K, Chen H T, Zhang S Z, Ren Y X 2009 Nanoelectronic Device & Technology 47 71 (in Chinese) [杨红伟, 黄科, 陈宏泰, 张世祖, 任永学 2009 纳米器件与技术 47 71]
[16]	Zhang J S, Ning Y Q, Zhang J L, Zhang J, Zhang J W, Wang L J 2014 Chinese J. Lasers 41 0107001 (in Chinese) [张金胜, 宁永强, 张金龙, 张建, 张建伟, 王立军 2014 中国激光 41 0107001]
[17]	Matthew P, Victor R, Bruno A 2005 Proc. SPIE 5711 142

施引文献

[1]	Calmano T, Siebenmorgen J, Paschke A G, Fiebig C, Paschke K, Erbert G, Petermann K, Huber G 2011 Opt. Mater. Express 3 428
[2]	Chen H P, Cao J S, Guo S X 2013 Acta Phys. Sin. 62 104209 (in Chinese) [陈海鹏, 曹军胜, 郭树旭 2013 物理学报 62 104209]
[3]	Zhou M Zhao D G 2016 Acta Phys. Sin. 65 077802 (in Chinese) [周梅, 赵德刚 2016 物理学报 65 077802]
[4]	Frevert C, Bugge F, Knigge S, Ginolas A, Erbert G, Crump P 2016 Proc. SPIE 9733 97330L
[5]	Yamagata Y, Yamada Y, Muto M, Sato S, Nogawa R, Sakamoto A, Yamaguchi M 2015 Proc. SPIE 9348 93480F
[6]	Pietrzak A, Huelsewede R, Zorn M, Hirsekorn O, Sebastian J, Meusel J, Bluemel V, Hennig P 2014 Proc. SPIE 8965 89650T
[7]	Crump P, Erbert G, Wenzel H, Frevert C, Schultz C M, Hasler K H, Staske R, Sumpf B, Maaßdorf A, Bugge F, Knigge S, Member, Trankle G 2013 IEEE J. Sel. Top. Quant. Electron. 19 1501211
[8]	Lauer C, König H, Grönninger G, Hein S, Alvaro G I, Furitsch M, Maric J, Kissel H, Wolf P, Biesenbach J, Strauß U 2012 Proc. SPIE 8241 824111
[9]	Cao C S, Fan L, Ai I, Li J, Caliva B, Zeng L F, Thiagarajan P, McElhinney M 2010 Proc. SPIE 7583 75830L
[10]	Hlsewede R, Schulze H, Sebastian J, Schröder D, Meusel J, Hennig P 2007 Proc. SPIE 6456 645607
[11]	Peters M, Rossin V, Everett M, Zucker E, Power H 2007 Proc. SPIE 6456 64560G
[12]	Crump P A, Crum T R, DeVito M, Farmer J, Grimshaw M, Huang Z, Igl S A, Macomber S, Thiagarajan P, Wise D 2004 Proc. SPIE 5336 144
[13]	Wang J, Smith B, Xie X M, Wang X Q, Burnham G T 1999 Appl. Phys. Lett. 74 1525
[14]	Zhong L, Wang J, Feng X M, Wang Y G, Wang C L, Han L, Chong F, Liu S P, Ma X Y 2007 Chinese J. Lasers 34 1038 (in Chinese) [仲莉, 王俊, 冯小明, 王勇刚, 王翠鸾, 韩琳, 崇锋, 刘素平, 马骁宇 2007 中国激光 34 1038]
[15]	Yang H W, Huang K, Chen H T, Zhang S Z, Ren Y X 2009 Nanoelectronic Device & Technology 47 71 (in Chinese) [杨红伟, 黄科, 陈宏泰, 张世祖, 任永学 2009 纳米器件与技术 47 71]
[16]	Zhang J S, Ning Y Q, Zhang J L, Zhang J, Zhang J W, Wang L J 2014 Chinese J. Lasers 41 0107001 (in Chinese) [张金胜, 宁永强, 张金龙, 张建, 张建伟, 王立军 2014 中国激光 41 0107001]
[17]	Matthew P, Victor R, Bruno A 2005 Proc. SPIE 5711 142

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