专家信息：

黄永箴，男，1963年1月生于福建省泉州市，博士，研究员，博士生导师，分别于1983年、1986年和1989年在北京大学物理系获得学士、硕士和博士学位，1989年进入中科院半导体研究所，2002年获得国家杰出青年科学基金。曾任集成光电子学国家重点联合实验室学术委员会主任，中科院半导体所学术委员会主任，中科院半导体所光电子研发中心主任和集成光电子学国家重点联合实验室主任。现任中国科学院半导体研究所二级研究员。

作为责人和主要骨干参加了多项国家自然科学基金重点和面上项目，以及973和863项目。研制出GaAs垂直腔面发射激光器和选择氧化垂直腔面发射激光器，1994年在英国电信实验室做访问学者，研制了1550nm InGaAsP垂直腔面发射激光器。率先研究获得介质二维正三角形、正方形和长方形微腔模式解析解，发现多边形微腔的高Q模式是模式耦合形成的驻波模式，适于研制直连波导输出多边形微腔激光器，解决了回音壁微腔激光器的波导定向输出及光子集成难题；利用微腔作为波长选择的反射镜，研制出高性能的单模可调谐半导体激光器和光双稳激光器，并实现高速全光信息处理；提出采用弧边多边形微腔模式工程，实现模式Q值和间隔调控，首次研制出模式作用自发混沌微腔激光器，实现500 Gb/s的随机数产生。

获得2005、2007、2015和2018年中科院优秀研究生指导教师奖， 2006年中科院研究生院优秀教师、2008年中科院宝洁优秀研究生导师奖，2019年中国科学院大学朱李月华优秀教师奖。培养的博士获得2005、2007、2015和2018年中科院优秀博士论文，以及2008年全国百篇优秀博士论文，并有七人次获得中国科学院院长优秀奖。他发表国内外刊物论文220多篇，申请获得多项发明专利，微腔激光器研究成果三次获得中国光学重要成果以及2020年中国光学学会光学科技奖一等奖。研究成果汇总为Microcavity Semiconductor Lasers专著由WILEY VCH出版(2021)。

教育经历：

1979年9月—1983年7月，在北京大学物理系固体物理专业学习，获学士学位。

1983年9月—1989年8月，为北京大学物理系研究生和博士研究生，分别于1986年和1989年获得硕士和博士学位。

1994年2月—1995年2月，在英国电信实验室做访问学者，从事InGaAsP VCSEL的研制。

主要科研工作经历：

1989年9月—1991年8月，中国科学院半导体研究所做博士后工作。

1992.06  聘为助理研究员。

1993.06  聘为副研究员。

1997.06  聘为研究员四级。

1998.01-2017.10  集成光电子学国家重点联合实验室半导体实验区主任。

2000.01-2003.04  光电子研究发展中心副主任。

2003.04-2007.09  光电子研究发展中心代理主任。

2007.06  聘为研究员三级。

2007.09-2017.10  光电子研究发展中心主任。

2009.01  聘为研究员二级。

2013.12-2019.08 集成光电子学国家重点联合实验室主任。

2017.09-2022.12 半导体所学术委员会主任。

学术任职：

1、Photonics Research编委（Associate Editor）和光子学报编委。

2、中国电子学会半导体和集成技术分会委员。

黄永箴研究员课题组：

课题组人员：

与毕业的研究生在黄昆先生像前合影（2010） 

毕业研究生及其论文题目:

国伟华博士：光学微腔及半导体激光器增益谱测量的研究(1998-2004) (获2003年中国科学院院长优秀奖和2005年中国科学院优秀博士论文)

金潮渊硕士：半导体光放大器的数值分析(2000-2003)

陆巧银博士：等边三角形光学微腔的研究(2001-2004)

邓盛凌硕士：量子点及量子点激光器特性的理论研究(2002-2005)

陈 沁博士：多边形微腔激光器和微腔滤波器的研究(2001-2006) (获2006年中国科学院院长优秀奖，2007年中国科学院优秀博士论文，和2008年全国百篇优秀博士论文)

赵洪泉博士：Si与InP键合研究及Si基InGaAsP激光器的研制(2003-2006)

罗贤树硕士：半导体微盘谐振腔的模式特性研究(2003-2006)

赵 伟硕士：多边形微腔激光器定向输出的理论研究(2004-2007)

胡永红博士：半导体微腔激光器及光放大器的研制(2004-2007)

肖金龙博士：量子点半导体光放大器稳态和动态特性研究(2004-2007)

杨跃德博士：光学微腔的模式耦合及微腔激光器的研究(2004-2009) （获2009年中国科学院院长优秀奖）

李 敬博士：中红外和红光微腔激光器的研究(2006-2009)

王世江博士：半导体微腔激光器和光学双稳态的研究(2005-2010) （获2010年中国科学院院长优秀奖）

车凯军博士：金属限制的正方形微腔激光器的研究与制作(2005-2010) （获2010年中国科学院院长优秀奖）

王世君博士：多边形及微环滤波器的研究(2005-2010)

曲连杰硕士：光子晶体慢光波导的结构设计与特性分析(2007-2010)

教授课程：

半导体激光器

科学研究：

研究方向：

主要研究半导体微腔激光器、半导体光放大器、量子点半导体激光器和光放大器、微腔光学滤波器、以及微腔激光器与硅光波导的混合集成及其在光互连上的应用技术。

承担主要科研项目： 

1、国家重点研发计划项目 “面向骨干网通信应用的400GE 光收发阵列芯片研究”(2020.05—2023.04，1370万元)；

2、国家自然科学基金重点项目“新型微纳光子器件与应用的基础研究”(2020.01—2024.12，297万元)；

3、基金委国家重大科学仪器研制项目 “基于双波长微腔激光器和非线性光纤的可调谐光频梳系统研制”(2016.01—2020.12，793万元)；

4、基金委/香港研究局合作项目“用于直接调制多波长输出和主动锁模的硅基III-V族材料耦合谐振腔波导激光器”(2015.01—2018.12，90万元)；

5、中国科学院前沿科学重点研究计划项目“ 片上集成量子纠缠光源研究”(2016.08—2020.12, 300万元)。

6、国家杰出青年科学基金：“微腔激光器的研制”，2003-2006。

7、“863”项目：“量子点光电子器件微观结构设计与性能预测研究”，2003-2005。

8、“973 ” 课题：微纳结构新型光电子集成器件及应用研究，2006-2010。

9、 国家基金重点项目：微纳尺度微腔激光器及量子效应研究，2009.01-2012.12 。

10、基于双波长微腔激光器和非线性光纤的可调谐光频梳系统，主持， 国家级，2016.01--2020.12。

11、新型半导体激光器及多功能光子集成基础研究，主持，国家级，2013.01-2017-12。

科研成果：

作为主要骨干参加了“863”项目垂直腔面发射激光器和InGaAs垂直腔面发射激光器的研制，在国内首次研制出GaAs垂直腔面发射激光器和选择氧化垂直腔面发射激光器。1994年在英国电信实验室做访问学者，研制了1550nm InGaAsP垂直腔面发射激光器。获得2002年国家杰出青年科学基金，重点研究光学微腔的模式特性并研制微腔激光器。十年来系统研究了适于光子集成的定向输出微腔半导体激光器，在国际上率先研究得出正三角形和正方形光学微腔的模式解析解，并研制出室温连续工作的正三角形和正方形光学微腔半导体激光器，以及带输出波导的圆形微腔半导体激光器。获得2008 年中科院半导体研究所优秀科研成果奖，

正方形光学微腔半导体激光器、微腔双稳态半导体激光器和定向输出圆形微腔激光器研究成果分别入选《激光与光电子学进展》杂志评选的2008、2009和2010年度中国光学重要成果。

获得五项中国发明专利和一项美国发明专利，发表SCI论文九十多篇。

国外发明专利：

1. Yongzhen Huang, Laser having equilateral triangular optical resonators of orient output, Patent No. US 6763052 B2

国内发明专利：

[1]白化宇,杨跃德,郝友增,肖金龙,黄永箴. 定向输出的变形正方形微腔半导体激光器[P]. CN115207768A,2022-10-18.

[2]张振宁,黄永箴,杨跃德,肖金龙. 半导体激光器[P]. CN115064936A,2022-09-16.

[3]李建成,黄永箴,黄勇涛,马春光,肖金龙,杨跃德. 多边形微腔混沌激光器及其调控方法[P]. CN115000812A,2022-09-02.

[4]郝友增,黄永箴,沈征征,绳梦伟,杨跃德,肖金龙. 抗反馈耦合腔半导体激光器[P]. CN114336281A,2022-04-12.

[5]绳梦伟,郝友增,黄永箴,杨跃德,肖金龙,刘家辰. 单片集成窄线宽耦合腔半导体激光器[P]. CN114050473A,2022-02-15.

[6]王玮,沈征征,陈幼玲,肖金龙,杨跃德,黄永箴. 半导体微腔激光器[P]. CN113991421A,2022-01-28.

[7]肖金龙,马春光,肖志雄,郝友增,杨跃德,黄永箴. 近简并多模微腔激光器、随机数产生装置及应用[P]. CN113437639A,2021-09-24.

[8]孟祥辉,杨跃德,黄永箴,肖金龙. 集成侧向调制器的FP激光器[P]. CN113097859A,2021-07-09.

[9]马春光,肖金龙,黄永箴,吴冀亮,杨跃德. 基于半导体双模微腔激光器的混沌信号产生装置及方法[P]. CN113036598A,2021-06-25.

[10]郝友增,黄永箴,杨跃德,肖金龙,王福丽,汤敏,翁海中. 可调谐耦合腔半导体激光器[P]. CN109638645A,2019-04-16.

[11]韩浚源,和田修,肖金龙,翁海中,王福丽,杨跃德,黄永箴. 一种太赫兹波发射器[P]. CN109038182A,2018-12-18.

[12]马秀雯,黄永箴,杨跃德,肖金龙,翁海中,王福丽,汤敏. 全光触发器[P]. CN106933000A,2017-07-07.

[13]隋少帅,唐明英,杜云,黄永箴. 稳定、定向输出微腔激光器[P]. CN106058640A,2016-10-26.

[14]肖志雄,肖金龙,吕晓萌,刘博文,黄永箴. 直接调制激光器微带制备方法及由此得到的微带和激光器[P]. CN105490136A,2016-04-13.

[15]隋少帅,黄永箴,唐明英,杨跃德,肖金龙,杜云. 一种多边形-环硅基激光器及其制备方法[P]. CN105140778A,2015-12-09.

[16]金鑫,黄永箴,肖金龙,杨跃德. 一种单模激射圆环微腔激光器[P]. CN104993374A,2015-10-21.

[17]金鑫,黄永箴,杨跃德,肖金龙. 一种定向输出的圆环微腔激光器[P]. CN104979751A,2015-10-14.

[18]马秀雯,杨跃德,肖金龙,刘博文,邹灵秀,龙衡,黄永箴. 基于耦合腔的单模高速调制法布里-珀罗半导体激光器[P]. CN104868359A,2015-08-26.

[19]龙衡,黄永箴,马秀雯,邹灵秀,肖金龙,杨跃德. 基于双模正方形微腔激光器的可调谐光频梳[P]. CN104765217A,2015-07-08.

[20]翁海中,黄永箴,邹灵秀,马秀雯,肖金龙,杨跃德,肖志雄. 一种基于单片集成微腔激光器的可调谐光频梳产生系统[P]. CN104765218A,2015-07-08.

[21]隋少帅,唐明英,杜云,黄永箴. 一种基于金属限制散热结构的硅基微腔激光器及其制作方法[P]. CN104283109A,2015-01-14.

[22]杨跃德,黄永箴. 基于氮化硅波导和微环的模式-波长复用器件的制备方法[P]. CN104111494A,2014-10-22.

[23]刘博文,杨跃德,邹灵秀,龙衡,马秀雯,黄永箴. 基于波导耦合微盘光子分子激光器的光脉冲同步信号源[P]. CN104078839A,2014-10-01.

[24]邹灵秀,黄永箴,吕晓萌,龙衡,刘博文,杜云. 集成化的基于光注入回音壁模式激光器的光电振荡器[P]. CN103944063A,2014-07-23.

[25]隋少帅,唐明英,杨跃德,肖金龙,杜云,黄永箴. 金属完全限制的硅基混合激光器的制备方法[P]. CN103887705A,2014-06-25.

[26]吕晓萌,邹灵秀,龙衡,黄永箴. 环形电极微腔激光器[P]. CN103811997A,2014-05-21.

[27]林建东,黄永箴,杨跃德,肖金龙,姚齐峰,吕晓萌,杜云. 基于两端口微腔激光器空间干涉的光学生物传感器[P]. CN102519910A,2012-06-27.

[28]王世江,黄永箴,杨跃德. 一种定向输出的圆盘微腔激光器[P]. CN101997267A,2011-03-30.

[29]于丽娟,杜云,赵烘泉,黄永箴. 硅基化合物半导体激光器的制作方法[P]. CN101997270A,2011-03-30.

[30]曲连杰,杨跃德,黄永箴. 光子晶体矩形耦合腔零色散慢光波导[P]. CN101887145A,2010-11-17.

[31]李敬,黄永箴,杨跃德. 一种量子级联正多边形微腔激光器及其制作方法[P]. CN101867147A,2010-10-20.

[32]王世江,黄永箴,杨跃德. 一种双谐振腔与波导的耦合结构[P]. CN101859979A,2010-10-13.

[33]车凯军,黄永箴. 微纳型半导体边发射FP激光器及其制作方法[P]. CN101764353A,2010-06-30.

[34]王世江,黄永箴,杨跃德. 侧向耦合输出波导的微腔激光器[P]. CN101741014A,2010-06-16.

[35]黄永箴,杨跃德,王世江. 正多边形微腔双稳半导体激光器[P]. CN101728760A,2010-06-09.

[36]黄永箴. 一种高输出效率的半导体发光管[P]. CN101567379,2009-10-28.

[37]赵伟,黄永箴. 带输出波导的正方形微腔激光器[P]. CN101325311,2008-12-17.

[38]杨跃德,黄永箴,罗贤树,陈沁. 基于TM模激射的圆柱形结构的微盘激光器[P]. CN101174757,2008-05-07.

[39]陈沁,杨跃德,黄永箴. 消除分布模式耦合的环形微腔波导滤波器及制作方法[P]. CN101079512,2007-11-28.

[40]罗贤树,黄永箴,陈沁. 制作半导体微盘激光器的方法[P]. CN101075726,2007-11-21.

[41]赵洪泉,于丽娟,黄永箴. 晶片直接键合过程中实验参数的优化方法[P]. CN1996551,2007-07-11.

[42]赵洪泉,于丽娟,黄永箴. 一种低温晶片直接键合方法[P]. CN1933096,2007-03-21.

[43]黄永箴. 一种增益钳制的半导体光放大器及制作方法[P]. CN1719325,2006-01-11.

[44]国伟华,黄永箴. 单模微腔半导体激光器[P]. CN1527449,2004-09-08.

[45]黄永箴. 面发射等边三角形谐振腔激光器[P]. CN1341987,2002-03-27.

[46]黄永箴. 具有等边三角形微光学谐振腔的光电器件[P]. CN1318887,2001-10-24.

[47]黄永箴. 等边三角形谐振腔半导体激光器[P]. CN1267106,2000-09-20.

[48]黄永箴. 单模垂直腔面发射半导体激光器[P]. CN1242633,2000-01-26.

发明授权：

[1]郝友增,黄永箴,杨跃德,肖金龙,王福丽,汤敏,翁海中. 可调谐耦合腔半导体激光器[P]. CN109638645B,2021-04-06.

[2]马秀雯,黄永箴,杨跃德,肖金龙,翁海中,王福丽,汤敏. 全光触发器[P]. CN106933000B,2020-01-21.

[3]肖志雄,肖金龙,吕晓萌,刘博文,黄永箴. 直接调制激光器微带制备方法及由此得到的微带和激光器[P]. CN105490136B,2018-10-02.

[4]金鑫,黄永箴,杨跃德,肖金龙. 一种定向输出的圆环微腔激光器[P]. CN104979751B,2018-09-11.

[5]金鑫,黄永箴,肖金龙,杨跃德. 一种单模激射圆环微腔激光器[P]. CN104993374B,2018-05-04.

[6]马秀雯,杨跃德,肖金龙,刘博文,邹灵秀,龙衡,黄永箴. 基于耦合腔的单模高速调制法布里-珀罗半导体激光器[P]. CN104868359B,2018-03-23.

[7]龙衡,黄永箴,马秀雯,邹灵秀,肖金龙,杨跃德. 基于双模正方形微腔激光器的可调谐光频梳[P]. CN104765217B,2017-11-17.

[8]翁海中,黄永箴,邹灵秀,马秀雯,肖金龙,杨跃德,肖志雄. 一种基于单片集成微腔激光器的可调谐光频梳产生系统[P]. CN104765218B,2017-11-17.

[9]刘博文,杨跃德,邹灵秀,龙衡,马秀雯,黄永箴. 基于波导耦合微盘光子分子激光器的光脉冲同步信号源[P]. CN104078839B,2017-04-19.

[10]邹灵秀,黄永箴,吕晓萌,龙衡,刘博文,杜云. 集成化的基于光注入回音壁模式激光器的光电振荡器[P]. CN103944063B,2017-01-25.

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论文专著：

发表期刊论文：

1.Y. L. Huang, Q. Li, J. Y. Han, Z. X. Jia，Y. S. Yu, Y. D. Yang, J. L. Xiao, J. L. Wu, D. M. Zhang, Y. Z. Huang, W. P. Qin, G. S. Qin, “Temporal soliton and optical frequency comb generation in a Brillouin laser cavity,” Optica, 6(12), 1491-1497, 2019.

2.H. Z. Weng, Y. D. Yang, J. L. Wu, Y. Z. Hao, M. Tang, J. L. Xiao, and Y. Z. Huang, “Dual-wavelength microlasers for microwave and optical frequency comb generation,” IEEE J. Sel. Top. Quantum Electron. 25(6) 1501408, 2019.

3.Y. Q. Ye, M. Tang, Y. H. Zhang, Y. D. Yang, J. L. Xiao, and Y. Z. Huang, “Mode and lasing characteristics for scissor-FP hybrid-cavity semiconductor lasers,” J. Opt. Soc. Am. B, 36(11), 3009-3015, 2019.

4.M. Tang, Y. D. Yang, H. Z. Weng, J. L. Xiao, and Y. Z. Huang, “Ray dynamics and wave chaos in circular-side polygonal microcavities,” Phys. Rev. A, 99(3), 033814, 2019.

5.Y. L. Chen and Y. Z. Huang, “Multinanoparticle scattering in a multimode microspheroid resonator,” Phys. Rev. A, 99(2), 023818, 2019

6.F. L. Wang, Y. Z. Huang, Y. D. Yang, C. G. Ma, Y. Z. Hao, M. Tang, and J. L. Xiao, “Study of optical bistability based on hybrid-cavity semiconductor lasers,” AIP advances, 9(4), 045224, 2019.

7.Y. Z. Hao, F. L. Wang, M. Tang, H. Z. Weng, Y. D. Yang, J. L. Xiao, and Y. Z. Huang, “Widely tunable single-mode lasers based on a hybrid square/rhombus-rectangular microcavity,” Photonics Res., 7(5), 543-548, 2019.

8.Y. D. Yang, M. Tang, F. L. Wang, Z. X. Xiao, J. L. Xiao, and Y. Z. Huang, “Whispering-gallery mode hexagonal micro-/nanocavity lasers,” Photonics Res., 7(5), 594-607, 2019.

9.J. Y. Han, Y. T. Huang, Y. Z. Hao, M. Tang, F. L. Wang, J. L. Xiao, Y. D. Yang, Y. Z. Huang, “Wideband frequency-tunable optoelectronic oscillator with a directly modulated AlGaInAs/InP integrated twin-square microlaser,” Opt. Express 26(24), 31784-31793, 2018.

10.Y. H. Zhang, H. Z. Weng, Y. D. Yang, J. L. Xiao, and Y. Z. Huang, “Mode coupling and competition in square-racetrack hybrid-cavity semiconductor lasers,” J. Opt. Soc. Am. B 34, 2674-2680, 2018.

11.Y. D. Yang, M. L. Liao, J. Y. Han J Y, H. Z. Weng, J. L. Xiao, and Y. Z. Huang, “Narrow-linewidth Microwave Generation by Optoelectronic Oscillators with AlGaInAs/InP Microcavity Lasers,” J. Lightw. Technol. 36, 4379-4385, 2018.

12.F. L. Wang, Y. D. Yang, Y. Z. Huang, Z. X. Xiao, and J. L. Xiao, "Single-transverse-mode waveguide-coupled deformed hexagonal resonator microlasers," Appl. Opt. 57, 7242-7248, 2018.

13.J. Y. Han, Y. Z. Huang, Y. Z. Hao, J. L. Wu, F. L. Wang, Y. D. Yang, and J. L. Xiao, “Low-phase-noise microwave generation using dual-mode microsquare laser phase locking by modulated sidebands,” Opt. Lett. 43, 4069-4072, 2018.

14.Y. Z. Huang, X. W. Ma, Y. D. Yang, J. L. Xiao, and Y. Du, "Hybrid-cavity semiconductor lasers with a whispering-gallery cavity for controlling Q factor," Sci. China Inf. Sci. 61, 080401, 2018.

15.M. L. Liao, J. L. Xiao, Y. Z. Huang, H. Z. Weng, J. Y. Han, Z. X. Xiao, and Y. D. Yang, “Tunable optoelectronic oscillator using a directly modulated microsquare laser,” IEEE Photon. Technol. Lett. 30, 1242-1245, 2018.

16.S. Liu, W. Z. Sun, Y. J. Wang, X. Y. Yu, K. Xu, Y. Z. Huang, S. M. Xiao, Q. H. Song, “End-fire injection of light into high-Q silicon microdisks,” Optica 5, 612-616, 2018.

17.H. Z. Weng, J. Y. Han, Q. Li, Y. D. Yang, J. L. Xiao, G. S. Qin, and Y. Z. Huang, “Optical frequency comb generation based on the dual-mode square microlaser and a nonlinear fiber loop,” Appl. Phys. B 124, 91, 2018.

18.H. Z. Weng, Y. D. Yang, J. L. Xiao, Y. Z. Hao, and Y. Z. Huang, “Spectral engineering for circular-side square microlasers,” Opt. Express 26, 9409-9414, 2018.

19.H. Z. Weng, Y. Z. Huang, X. W. Ma, Y. D. Yang, J. L. Xiao, J. Y. Han, and M. L. Liao, “Optical frequency comb generation in highly nonlinear fiber with dual-mode square microlasers,” IEEE Photon. J. 10, 7102009, 2018.

20.F. L. Wang, X. W. Ma, Y. Z. Huang, Y. D. Yang, J. Y. Han, and J. L. Xiao, "Relative intensity noise in high-speed hybrid square-rectangular lasers," Photon. Res. 6, 193-197, 2018.

21.M. Tang, Y. Z. Huang, Y. D. Yang, H. Z. Weng, and Z. X. Xiao, "Variable-curvature microresonators for dual-wavelength lasing," Photon. Res. 5, 695-701, 2017.

22.H. Z. Weng, Y. Z. Huang, X. W. Ma, F. L. Wang, M. L. Liao, Y. D. Yang, and J. L. Xiao, “Spectral Linewidth Analysis for Square Microlasers,” IEEE Photon. Technol. Lett. 29,1931-1934, 2017.

23.X. W. Ma, Y. Z. Huang, Y. D. Yang, H. Z. Weng, J. L. Xiao, M. Tang, and Y. Du, "Mode and Lasing Characteristics for Hybrid Square-Rectangular Lasers," IEEE J. Sel. Top. Quantum Electron. 23, 1500409, 2017

24.M. L. Liao, Y. Z. Huang, H. Z. Weng, J. Y. Han, Z. X. Xiao, J. L. Xiao, and Y. D. Yang, Liao Ming-Long, "Narrow-linewidth microwave generation by an optoelectronic oscillator with a directly modulated microsquare laser," Opt. Lett. 42, 4251-4254, 2017.

25.S. S. Sui, Y. Z. Huang, M. Y. Tang, Y. D. Yang, J. L. Xiao, and Y. Du, “Hybrid deformed-ring AlGaInAs/Si microlasers with stable unidirectional emission,” IEEE J. Sel. Top. Quantum Electron. 23, 1500308, 2017.

26.Z. X. Xiao, Y. Z. Huang, Y. D. Yang, M. Tang, and J. L. Xiao, "Modulation bandwidth enhancement for coupled twin-square microcavity lasers," Opt. Lett. 42, 3173-3176, 2017.

27.H. Z. Weng, O. Wada, J. Y. Han, J. L. Xiao, Y. D. Yang, Y. Z. Huang, J. Li, B. Xiong, C. Z. Sun, and Y. Luo, “Sub-THz wave generation based on a dual wavelength microsquare laser,” Electron. Lett. 53, 939-941, 2017.

28.X. W. Ma, Y. Z. Huang, Y. D. Yang, H. Z. Weng, F. L. Wang, M. Tang, J. L. Xiao, and Y. Du, "All-optical flip-flop based on hybrid square-rectangular bistable lasers," Opt. Lett. 42, 2291-2294, 2017.

29.Z. X. Xiao, Y. Z. Huang, Y. D. Yang, J. L. Xiao, and X. W. Ma, "Single-mode unidirectional-emission circular-side hexagonal resonator microlasers," Opt. Lett. 42, 1309-1312, 2017.

30.H. Z. Weng, Y. Z. Huang, Y. D. Yang, X. W. Ma, J. L. Xiao, and Y. Du, “Mode Q factor and lasing spectrum controls for deformed square resonator microlasers with circular sides,” Phys. Rev. A 95, 013833, 2017.

31.X. W. Ma, Y. Z. Huang, H. Long, Y. D. Yang, F. L. Wang, J. L. Xiao, and Y. Du, “Experimental and theoretical analysis of dynamical regimes for optically injected microdisk lasers,” J. Lightwave. Technol. 34, 5263-5269, 2016.通讯作者

32.H. Z. Weng, Y. Z. Huang, J. L. Xiao, Y. D. Yang, X. W. Ma, F. L. Wang, and Y. Du, “Multicoherence wavelength generation based on integrated twin-microdisk lasers,” Opt. Lett. 41, 5146-5149(2016).通讯作者

33.Y. Z. Huang, X. W. Ma, Y. D. Yang, and J. L. Xiao, “Review of the dynamic characteristics of AlGaInAs/InP microlasers subject to optical injection,” Semicond. Sci. Technol. 31, 113002, 2016. 

34.X. Jin, Y. D. Yang, J. L. Xiao, and Y. Z. Huang, “Mode control for microring resonators with inner-wall gratings,” J. Opt. Soc. Am. B 33, 1906-1912, 2016.通讯作者

35.S. S. Sui, Y. Z. Huang, M. Y. Tang, H. Z. Weng, Y. D. Yang, J. L. Xiao, and Y. Du, “Locally deformed-ring hybrid microlasers exhibiting stableunidirectional emission from a Si waveguide,” Opt. Lett. 41, 3928-3931, 2016.通讯作者

36.X. W. Ma, Y. Z. Huang, Y. D. Yang, J. L. Xiao, H. Z. Weng, and Z. X. Xiao, "Mode coupling in hybrid square-rectangular lasers for single mode operation," Appl. Phys. Lett. 109, 071102, 2016.通讯作者

37.Y. D. Yang, Y. Z. Huang, “Mode characteristics and directional emission for square microcavity lasers,” J. Phys. D-Appl. Phys. 49, 253001, 2016 通讯作者

38.S. S. Sui, M. Y. Tang, Y. D. Yang, J. L. Xiao, Y. Du, and Y. Z. Huang, “Single-mode hybrid AlGaInAs/Si octagonal-ring microlaser with stable output,” Chin. Opt. Lett. 14, 031402, 2016.通讯作者

39.R. Lu, J. L. Xiao, Y. D. Yang, H. Z. Weng, H. Long, B. X. Bo, and Y. Z. Huang, “Unidirectional emission cut-corner square microcavity lasers,” IEEE J. Quantum Electron. 52, 2000105, 2016.通讯作者

40.C. C. Guo, J. L. Xiao, Y. D. Yang, Z. H. Zhu, Y. Z. Huang, “Lasing characteristics of wavelength-scale aluminum/silica coated square cavity,” IEEE Photon. Technol. Lett. 28, 217-220, 2016.

41.S. S. Sui, M. Y. Tang, Y. D. Yang, J. L. Xiao, Y. Du, and Y. Z. Huang, “Investigation of hybrid microring lasers adhesively bonded on silicon wafer,” Photon. Res. 3, 289-295, 2015

42.M. Y. Tang, S. S. Sui, Y. D. Yang, J. L. Xiao, and Y. Z. Huang, “Numerical investigation of metal-confined hybrid III-V/Si circular nanoresonator with guided emission,” Opt. Commun. 355, 306-312, 2015.

43.Y. D. Yang, H. Z. Weng, B. W. Liu, J. L. Xiao, and Y. Z.Huang, “Localized-cavity-loss-induced external mode coupling in optical microresonators,” J. Opt. Soc.Am. B 32, 2376-2381, 2015.

44.S. S. Sui, M. Y. Tang, Y. D. Yang, J. L. Xiao, Y. Du, and Y. Z. Huang, “Hybrid spiral-ring microlaser vertically coupled to silicon waveguide for stable and unidirectional output,” Opt. Lett. 40, 4995-4998, 2015.通讯作者

45.H. Long, Y. Z. Huang, Y. D. Yang, L. X. Zou, J. L. Xiao, Z. X. Xiao, "Mode and modulation characteristics for microsquare lasers with a vertex output waveguide," Science China: Physics, Mechanics & Astronomy 58, 114205, 2015.

46.L. X. Zou, Y. Z. Huang, B. W. Liu, X. M. Lv, H. Long, Y. D. Yang, J. L. Xiao, and Y. Du, “Nonlinear dynamics for semiconductor microdisk laser subject to optical injection,” IEEE J. Sel. Top. Quantum Electron. 21, 1800408, 2015.通讯作者

47.M. Y. Tang, S. S. Sui, Y. D. Yang, J. L. Xiao, Y. Du, and Y. Z. Huang, “Mode selection in square resonator microlasers for widely tunable single mode lasing,” Opt. Express 23, 27739-27750, 2015.

48.L. X. Zou, Y. Z. Huang, X. M. Lv, X. W. Ma, J. L. Xiao, Y. D. Yang, and Y. Du, “Single-mode microdisk laser with two ports for heptagonal coupled mode lasing,” Electron. Lett. 51, 1442-1443, 2015.

49.X. Jin, Y. D. Yang, J. L. Xiao, and Y. Z. Huang, “Proposal and simulation of microring resonators with partially distributed gratings for realizing unidirectional emission,” IEEE J. Quantum Electron. 51, 6500208, 2015.

50.B. W. Liu, Y. Z. Huang, H. Long, Y. D. Yang, J. L. Xiao, L. X. Zou, Y. Du, “Microwave generation direct from microsquare laser subject to optical injection,” IEEE Photon. Technol. Lett. 27, 1853-1856, 2015.通讯作者

51.X. W. Ma, Y. Z. Huang, L. X. Zou, B. W. Liu, H. Long, H. Z. Weng, Y. D. Yang, J. L. Xiao, “Narrow-linewidth microwave generation using optically injected AlGaInAs/InP microdisk lasers subject to optoelectronic feedback,” Opt. Express 23, 20321-20331, 2015.

52.H. Long, Y. Z. Huang, X. W. Ma, Y. D. Yang, J. L. Xiao, L. X. Zou and B. W. Liu, “Dual-transverse-mode microsquare lasers with tunable wavelength interval,” Opt. Lett. 40, 3548-3551, 2015.

53.Y. Z. Huang, L. X. Zou, B. W. Liu, Y. D. Yang, H. Long, J. L. Xiao, and Y. Du, “Dynamic and mode characteristics for AlGaInAs/InP microdisk lasers subject to optical injection,” Opt. Eng. 54, 076109, 2015.

54.J. F. Ku, Q. D. Chen, X. W. Ma, Y. D. Yang, Y. Z. Huang, H. L. Xu, H. B. Sun, “Photonic-molecular single-mode laser,” IEEE Photon. Technol. Lett. 27, 1157-1160, 2015.

55.L. X. Zou, B. W. Liu, X. M. Lv, Y. D. Yang, J. L. Xiao, and Y. Z. Huang, "Integrated semiconductor twin-microdisk laser under mutually optical injection," Appl. Phys. Lett. 106, 191107, 2015.通讯作者

56.S. S. Sui, M. Y. Tang, Y. D. Yang, J. L. Xiao, Y. Du, and Y. Z. Huang, “Mode investigation for hybrid microring lasers with sloped sidewalls coupled to a silicon waveguide,” IEEE Photon. J. 7, 6100209, 2015.通讯作者

57.S. S. Sui, M. Y. Tang, Y. D. Yang, J. L. Xiao, Y. Du, and Y. Z. Huang, “Sixteen-wavelength hybrid AlGaInAs/Si microdisk laser array,” IEEE J. Quantum Electron. 51, 2600108, 2015.通讯作者

58.S. S. Sui, M. Y. Tang, Y. Z. Huang, Y. D. Yang, J. L. Xiao, and Y. Du, “Eight-wavelength hybrid Si/AlGaInAs/InP microring laser array,” Electron. Lett. 51, 506-508, 2015. 通讯作者

59.Y. D. Yang, J. L. Xiao, B. W. Liu, and Y. Z. Huang, “Mode characteristics and vertical radiation loss for AlGaInAs/InP microcylinder lasers,” J. Opt. Soc. Am. B 32, 439-444, 2015.

60.H. Long, Y. Z. Huang, Y. D. Yang, L. X. Zou, J. L. Xiao, X. W. Ma, X. M. Lv, B. W. Liu, and Y. Du, “High-Speed Direct-Modulated Unidirectional Emission Square Microlasers,” J. Lightwave Technol. 33, 787-794, 2015.通讯作者

61.L. X. Zou, Y. Z. Huang, B. W. Liu, X. M. Lv, X. W. Ma, Y. D. Yang, J. L. Xiao, and Y. Du, “Thermal and high speed modulation characteristics for AlGaInAs/InP microdisk lasers,” Opt. Express 23, 2879-2888, 2015.通讯作者

62.L. X. Zou, Y. Z. Huang, X. M. Lv, B. W. Liu, H. Long, Y. D. Yang, J. L. Xiao, and Y. Du, “Modulation characteristics and microwave generation for AlGaInAs/InP microring lasers under four-wave mixing,” Photon. Res. 2, 177-181, 2014.

63.H. Long, Y. Z. Huang, Y. D. Yang, L. X. Zou, X. M. Lv, B. W. Liu, J. L. Xiao, and Y. Du, “Mode characteristics of unidirectional emission AlGaInAs/InP square resonator microlasers,” IEEE J. Quantum Electron. 50, 981-989, 2014.通讯作者

64.X. W. Ma, X. M. Lv, Y. Z. Huang, Y. D. Yang, J. L. Xiao, and Y. Du, “Mode characteristics for unidirectional-emission microring resonator lasers,” J. Opt. Soc. Am. B 31, 2773-2778, 2014.

65.L. X. Zou, Y. Z. Huang, X. M. Lv, H. Long, J. L. Xiao, Y. D. Yang, and Y.Du, “Dynamic characteristics of AlGaInAs/InP octagonal resonator microlaser,” Appl. Phys. B 117, 453-458, 2014. 通讯作者

66.H. Long, Y. Z. Huang, L. X. Zou, Y. D. Yang, X. M. Lv, X. W. Ma, and J. L Xiao, “Investigation of high efficiency unidirectional emission from metal coated nanocylinder cavities,” J. Lightwave. Technol. 32(18), 3192-3198, 2014.

67.Y. D. Yang, Y. Li, Y. Z. Huang, A. W. Poon, “Silicon nitride three-mode division multiplexing and wavelength-division multiplexing using asymmetrical directional couplers and microring resonators,” Opt. Express 22, 22172-22183, 2014.

68.X. M. Lv, Y. D. Yang, L. X. Zou, H. Long, J. L. Xiao, Y. Du, and Y. Z. Huang, “Mode Characteristics and Optical Bistability for AlGaInAs/InP Microring Lasers,” IEEE Photon. Technol. Lett. 26, 1703-1706, 2014.

69.X. M. Lv, Y. Z. Huang, Y. D. Yang, L. X. Zou, H. Long, B. W. Liu, J. L. Xiao, and Y. Du, “Influences of carrier diffusion and radial mode field pattern on high speed characteristics for microring lasers,” Appl. Phys. Lett. 104, 161101, 2014.通讯作者

70.Y. Z. Huang, X. M. Lv, L. X. Zou, H. Long, J. L. Xiao, Y. D. Yang, and Y. Du, “Investigations on high speed directly modulated microdisk lasers accounting for radial carrier hole burning,” Opt. Eng. 53, 046104, 2014.

71.C. C. Guo, J. L. Xiao, Y. D. Yang, and Y. Z. Huang, “Mode characteristics of subwavelength aluminum/silica-coated InAlGaAs/InP circular nanolasers,” J. Opt. Soc. Am. B. 31, 865-872, 2014.

72.Y. D. Yang, Y. Zhang, Y. Z. Huang, A. W. Poon, “Direct-modulated waveguide-coupled microspiral disk lasers with spatially selective injection for on-chip optical interconnects,” Opt. Express 22, 824-838, 2014.

73.K. J. Che, M. X. Lei, G. Q. Gu, Z. P. Cai, and Y. Z. Huang, “Optical processing between two metallically hybrid microdisks” Appl. Opt. 52, 8190-8194, 2013.

74.L. X. Zou, X. M. Lv, Y. Z. Huang, H. Long, Q. F. Yao, J. L. Xiao, and Y. Du, “Four-wavelength microdisk laser array laterally coupled with a bus waveguide,” Opt. Lett. 38(19), 3807-3810, 2013.通讯作者

75.X. M. Lv, Y. Z. Huang, L. X. Zou, H. Long, J. L. Xiao, Y. D. Yang, Y. Du, “High-speed direct modulation unidirectional emission microring lasers,” Electron. Lett. 49, 1290-1291, 2013.通讯作者

76.X. M. Lv, Y. Z. Huang, L. X. Zou, H. Long, and Y. Du, "Optimization of direct modulation rate for circular microlasers by adjusting mode Q factor," Laser Photon. Rev. 7, 818-829, 2013.通讯作者

77.L. X. Zou, X. M. Lv, Y. Z. Huang, H. Long, J. L. Xiao, Q. F. Yao, J. D. Lin and Y. Du, "Mode analysis for unidirectional emission AlGaInAs/InP octagonal resonator microlasers," IEEE J. Sel. Top. Quantum Electron. 19, 1501808, 2013.通讯作者

78.X. M. Lv, Y. Z. Huang, Y. D. Yang, H. Long, L. X. Zou, Q. F. Yao, X. Jin, J. L. Xiao, and Y. Du, “Analysis of vertical radiation loss and far-field pattern for microcylinder lasers with an output waveguide,” Opt. Express 21(13), 16069-16074, 2013.通讯作者

79.Q. F. Yao, Y. Z. Huang, Y. D. Yang, L. X. Zou, X. M. Lv, H. Long, J. L. Xiao, and C. C. Guo, "Mode analysis for metal-coated nanocavity by three-dimensional S-matrix method," J. Opt. Soc. Am. B 30, 1335-1341, 2013.通讯作者

80.H. H. Fang, R. Ding, S. Y. Lu, Y. D. Yang, Q. D. Chen, J. Feng, Y. Z. Huang, H. B. Sun, “Whispering-gallery mode lasing from patterned molecular single-crystalline microcavity array,” Laser Photon. Rev. 7, 281-288, 2013.

81.J. L. Xiao, C. C. Guo, H. M. Ji, P. F. Xu, Q. F. Yao, X. M. Lv, L. X. Zou, H. Long, T. Yang, and Y. Z. Huang, “Measurement of Linewidth Enhancement Factor for 1.3-μm InAs/GaAs Quantum Dot Lasers,” IEEE Photon. Technol. Lett. 25(5), 488-491, 2013.通讯作者

82.Y. Z. Huang, X. M. Lv, J. D. Lin, and Y. Du, “Output characteristics of square and circular resonator microlasers connected with two output waveguides,” Sci. China Tech. Sci. 56(3), 538-542, 2013.

83.Q. F. Yao, Y. Z. Huang, L. X. Zou, X. M. Lv, J. D. Lin, and Y. D. Yang, "Analysis of mode coupling and threshold gain control for nanocircular resonators confined by isolation and metallic layers," J. Lightwave Technol. 31, 786-792, 2013.通讯作者

84.Q. F. Yao, Y. Z. Huang, J. D. Lin, X. M. Lv, L. X. Zou, H. Long, Y. D. Yang, and J. L. Xiao, “High-Q modes in defected microcircular resonator confined by metal layer for unidirectional emission,” Opt. Express 21(2), 2165-2170, 2013.

85.Y. Z. Huang, J. D. Lin, Q. F. Yao, X. M. Lu, Y. D. Yang, J. L. Xiao, and Y. Du, "AlGaInAs/InP coupled-circular microlasers," Chin. Opt. Lett. 10(9), 091404, 2012.

86.J. D. Lin, L. X. Zou, Y. Z. Huang, Y. D. Yang, Q. F. Yao, X. M. Lv, J. L. Xiao, and Y. Du, "Wide-angle emission and single-mode deformed circular microlasers with a flat side," Appl. Opt. 51(17), 3930-3935, 2012. 通讯作者

87.J. D. Lin, Y. Z. Huang, Y. D. Yang, Q. F. Yao, X. M. Lv, J. L. Xiao, and Y. Du, "Coherence of a single mode InAlGaAs/InP cylinderical microlaser with two output ports," Opt. Lett. 37(11), 1977-1979, 2012. 通讯作者

88.X. M. Lv, L. X. Zou, J. D. Lin, Y. Z. Huang, Y. D. Yang, Q. F. Yao, J. L. Xiao, and Y. Du, "Unidirectional-Emission Single-Mode AlGaInAs-InP Microcylinder Lasers," IEEE Photon. Technol. Lett. 24(11), 963-965, 2012. 通讯作者

89.X. M. Lv, L. X. Zou, Y. Z. Huang, Y. D. Yang, J. L. Xiao, Q. F. Yao, and J. D. Lin, "Influence of Mode Q Factor and Absorption Loss on Dynamical Characteristics for Semiconductor Microcavity Lasers by Rate Equation Analysis," IEEE J. Quantum Electron. 47(12), 1519-1525, 2011.通讯作者　

90.K. J. Che, Q. F. Yao, Y. Z. Huang, Z. P. Cai, Y. D. Yang, and Y. Du, "Multiple-Port InP/InGaAsP Square-Resonator Microlasers," IEEE J. Select. Topics Quantum Electron. 17(6), 1656-1661, 2011.

91.Y. D. Yang and Y. Z. Huang, "Investigation of Vertical Leakage Loss for Whispering-Gallery Modes in Microcylinder Resonators," J. Lightwave Technol. 29(18), 2754-2760, 2011.

92.K. J. Che, Y. Z. Huang, L.Chen, Z. P. Cai, and H. Y. Xu, “Metallically confined microdisks with in-plane multiple guided emissions,” Opt. Express 19(19), 18116–18121, 2011.

93.J. D. Lin, Y. Z. Huang, Y. D. Yang, Q. F. Yao, X. M. Lv, J. L. Xiao, and Y. Du, "Optical bistability in GaInAsP/InP coupled-circular resonator microlasers," Opt. Lett. 36(17), 3515-3517, 2011.通讯作者　

94.J. D. Lin, Y. Z. Huang, Q. F. Yao, X. M. Lv, Y. D. Yang, J. L. Xiao, and Y. Du, "InAlGaAs/InP cylinder microlaser connected with two waveguides," Electron. Lett. 47(16), 929-930, 2011.通讯作者　

95.J. D. Lin, Y. Z. Huang, Y. D. Yang, Q. F. Yao, X. M. Lv, J. L. Xiao, and Y. Du, "Single Transverse Whispering-Gallery Mode AlGaInAs/InP Hexagonal Resonator Microlasers," IEEE Photon. J. 3(4), 756-764, 2011.通讯作者　

96.K. J. Che, Y. Z. Huang, H. Y. Xu, and Z. P. Cai, “Port output of metallo-dielectric confined circular microlasers Port output of metallo-dielectric confined circular microlasers,” Opt. Lett. 36(8), 1374-1376, 2011

97.Y. Z. Huang, S. J. Wang, Y. D. Yang, J.D. Lin, K. J. Che, J. L. Xiao, and Y. Du, “Investigation on multiple-port microcylinder lasers based on coupled modes,” Semicond. Sci. Technol. 25(10), 105005, 2010.

98.S. J. Wang, J. D. Lin, Y. Z. Huang, Y. D. Yang, K. J. Che, J. L. Xiao, Y. Du, and Z. C. Fan, “AlGaInAs/InP microcylinder lasers connected with an output waveguide,” IEEE Photon. Technol. Lett. 22, 1349-1351, 2010.

99.K. J. Che, J. D. Lin, Y. Z. Huang, Y. D. Yang, J. L. Xiao, and Y. Du, “InGaAsP/InP square microlasers with a vertex output waveguide,” IEEE Photon. Technol. Lett. 22, 1370-1372, 2010.通讯作者　

100.S. J. Wang, Y. D. Yang, and Y. Z. Huang, “Analysis of coupled microcircular resonators coupled to a bus waveguide with high output efficiency,” Opt. Lett. 35(12), 1953-1955, 2010.

101.Y. D. Yang, Y. Z. Huang, W. H. Guo, Q. Y. Lu, and J. F. Donegan, “Enhancement of quality factor for TE whispering-gallery modes in microcylinder resonators, ” Opt. Express 18(12), 13057–13062, 2010.

102.K. J. Che and Y. Z. Huang, “Mode characteristics of metallically coated square microcavity connected with an output waveguide,” J. Appl. Phys. 107, 113103, 2010.

103.Y. D. Yang, S. J. Wang, and Y. Z. Huang, “Investigation of mode radiation loss for microdisk resonators with pedestals by FDTD technique,” Chin. Opt. Let. 8(5), 502-504, 2010.

104.K. J. Che, J. D. Lin, Y. Z. Huang, Y. D. Yang, and Y. Du, “Two-port InGaAsP/InP square resonator microlasers, ” Electron. Lett. 46(8), 585-586, 2010.

105.J. Li, Y. D. Yang, and Y. Z. Huang, “Mode simulation for midinfrared microsquare resonators with sloped sidewalls and confined metals, ” IEEE Photon. Technol. Lett. 22(7), 459-461, 2010.

106.S. J. Wang, Y. Z. Huang, Y. D. Yang, J. D. Lin, K. J. Che, J. L. Xiao, and Y. Du, “Long rectangle resonator 1550 nm AlGaInAs/InP lasers,” J. Opt. Soc. Am. B 27(4), 719-724, 2010.

107.K. J. Che, Y. D. Yang, and Y. Z. Huang, “Mode characteristics for square resonators with a metal confinement layer,” IEEE J. Quantum Electron. 46(3), 414-420, 2010.

108.K. J. Che, Y. D. Yang, and Y. Z. Huang, “Multimode resonances in metallically confined square-resonator Microlasers,” Appl. Phys. Lett. 96(5), 051104, 2010.

109.S. J. Wang, Y. Z. Huang, Y. D. Yang, Y. H. Hu, J. L. Xiao, and Y. Du, “Output characteristics of an InP/InGaAsP triangle microcavity laser,” Chin. Phys. Lett. 27(1), 014213, 2010.

110.Y. D. Yang, S. J. Wang, and Y. Z. Huang, “Investigation of mode coupling in a microdisk resonator for realizing directional emission,” Opt. Express 17(25), 23010–23015, 2009.

111.Y. D. Yang, Y. Z. Huang, and S. J. Wang, “Mode analysis for equilateral-triangle-resonator microlasers with metal confinement layers,” IEEE J. Quantum Electron. 45(12), 1529-1536, 2009.

112.S. J. Wang, Y. D. Yang, and Y. Z. Huang, “Analysis of mode characteristics for equilateral-polygonal resonators with a center hole,” J. Opt. Soc. Am. B 26(12), 2449-2454, 2009.

113.Y. Z. Huang, Y. D. Yang, S. J. Wang, J. L. Xiao, K. J. Che, and Y. Du, “Whispering-gallery microcavity semiconductor lasers suitable for photonic integrated circuits and optical interconnects,” Sci China Ser E-Tech 52(12), 3447-3453, 2009.

114.Y. Z. Huang and Y. D. Yang, “Calculation of light delay for coupled microrings by FDTD technique and Padé approximation,” J. Opt. Soc. Am. A 26(11), 2419-2426, 2009.

115.J. Li, Y. D. Yang, and Y. Z. Huang, “Design of quantum cascade microcavity lasers based on Q factor versus etching depth,” J. Opt. Soc. Am. B 26(8), 1484-1491, 2009.

116.Y. Z. Huang, S. J. Wang, Y. D. Yang, J. L. Xiao, Y. H. Hu, and Y. Du, “Optical bistability in InP/GaInAsP equilateral-triangle-resonator microlasers,” Opt. Lett. 34(12), 1852-1854, 2009.

117.J. L. Xiao, Y. D. Yang, and Y. Z. Huang, “Investigation of gain recovery for InAs/GaAs quantum dot semiconductor optical amplifiers by rate equation simulation,” Opt Quant Electron. 41(8), 613-626, 2009

118.Y. D. Yang, and Y. Z. Huang, K. J. Che, S. J. Wang, Y. H. Hu, and Y. Du, “Equilateral-triangle and square resonator semiconductor microlasers,” IEEE J. Sel. Top. Quantum Electron. 15(3), 879-884, 2009.

119.Y. Z. Huang, K. J. Che, Y. D. Yang, S. J. Wang, Y. Du, and Z. C. Fan, “Directional emission InP/GaInAsP square-resonator microlasers,” Opt. Lett. 33(19), 2170-2172, 2008.

120.J. L. Xiao and Y. Z. Huang, “Numerical analysis of gain saturation, noise figure, and carrier distribution for quantum-dot semiconductor-optical amplifiers,” IEEE J. Quantum Electron. 44(5), 448-455, 2008.

121.Y. Z. Huang and Y. D. Yang, “Mode coupling and vertical radiation loss for whispering-gallery modes in 3-D microcavities,” J. Lightwave. Technol. 26(11), 1411-1416, 2008.

122.Y. D. Yang and Y. Z. Huang, “Mode analysis and Q-factor enhancement due to mode coupling in rectangular resonators,” IEEE J. Quantum Electron. 43(6), 497-502, 2007.

123.Y. D. Yang and Y. Z. Huang, “Symmetry analysis and numerical simulation of mode characteristics for equilateral-polygonal optical microresonators,” Phys. Rev. A 76, 023822, 2007.

124.Q. Chen, Y. H. Hu, Y. Z. Huang, Y. Du, and Z. C. Fan, “Equilateral-triangle-resonator injection lasers with directional emission,” IEEE J. Quantum Electron. 43(6), 440-444, 2007.

125.Y. D. Yang, Y. Z. Huang, and Q. Chen, “Comparison of Q-factors between TE and TM modes in 3-D microsquares by FDTD simulation,” IEEE Photon. Technol. Lett. 19(22), 1831-1833, 2007.

126.Y. D. Yang, Y. Z. Huang, and Q. Chen, “High-Q TM whispering-gallery modes in three-dimensional microcylinders, ” Phys. Rev. A 75(1), 013817, 2007.

127.J. J. Li, J. X. Wang, and Y. Z. Huang, “Mode coupling between first- and second-order whispering-gallery modes in coupled microdisks,” Opt. Lett. 32(7), 1563-1565, 2007.

128.Q. Chen, Y. D. Yang, and Y. Z. Huang, “Finite-difference time-domain analysis of deformed square cavity filters with a traveling-wave-like filtering response by mode coupling,” Opt. Lett. 32(8), 967-969, 2007.

129.Q. Chen, Y. D. Yang, and Y. Z. Huang, “Prediction and suppression of strong dispersive coupling in microracetrack channel drop filters,” Opt. Lett. 32(13), 1851-1853, 2007.

130.J. L. Xiao, Y. Z. Huang, Y. Du, H. Zhao, H. Q. Ni, Z. C. Niu, “Gain measurement and anomalous decrease of peak gain at long wavelength for InAs/GaAs quantum-dot lasers,” Chin, Phys. Lett. 24(10), 2984-2986, 2007.

131.H. Q. Zhao, L. J. Yu, Y. Z. Huang, “Investigation of a chemically treated InP(1 0 0) surface during hydrophilic wafer bonding process,” Mater. Sci. & Eng. B 128, 93-97, 2006.

132.H. Q. Zhao, L. J. Yu, Y. Z. Huang, Y. T. Wang, “Strain analysis of InP/InGaAsP wafer bonded on Si by X-ray double crystalline diffraction,” Mater. Sci. & Eng. B 133, 117-123, 2006.

133.H. Q. Zhao, L. J. Yu, Y. Z. Huang, “Thermal stress analysis for GaInAsP multiple quantum well wafer chemically bonded to Si(100),” J. Appl. Phys. 100(2), 023513, 2006.

134.Q. Chen, Y. D. Yang, and Y. Z. Huang, “Distributed mode coupling in microring channel drop filters,” App. Phys. Lett. 89(6), 061118, 2006.

135.Y. Z. Huang, Q. Chen, W. H. Guo, Q. Y. Lu and L. J. Yu, “Mode characteristics for equilateral triangle optical resonators,” IEEE J. Sel. Top. Quantum Electron. 12(1), 59-65, 2006.

136.Q. Chen, Y. Z. Huang, and L. J. Yu, “Analysis of mode characteristics for deformed square resonators by FDTD technique,” IEEE J. Quantum Electron. 42(1), 59-63, 2006.

137.Q. Chen and Y. Z. Huang, “WG-like modes selectivity in a square cavity with posts,” Chin. Phys. Lett. 23(6), 1470-1472, 2006.

138.Q. Chen and Y. Z. Huang, “Investigation of mode characteristics for a square cavity with a pedestal by a three-dimensional finite-difference time-domain technique,” J. Opt. Soc. Am. B 23(7), 1287-1291, 2006.

139.W. Zhao and Y. Z. Huang, “Analysis of directional emission in square resonator lasers with an output waveguide,” Chin. Opt. Let. 23(6), 1470-1472, 2006.

140.X. S. Luo, Y. Z. Huang, and Q. Chen, “Mode-coupling analysis of three-dimensional microdisk resonators by the finite-difference time-domain technique,” Opt. Lett. 31(8), 1073-1075, 2006.

141.X. S. Luo, Y. Z. Huang, W. H. Guo, Q. Chen, M. Q. Wang, and L. J. Yu, “Investigation of mode characteristics for microdisk resonators by S-matrix and three-dimensional finite-difference time-domain technique,” J. Opt. Soc. Am. B 23(6), 1068-1073, 2006.

142.M. Q. Wang, Y. Z. Huang, Q. Chen, and Z. P. Cai, “Analysis of mode quality factors and mode reflectivities for nanowire cavity by FDTD technique,” IEEE J. Quantum Electron. 42(2), 146-151, 2006.

143.Q. Chen, Y. Z. Huang, W. H. Guo, and L. J. Yu, “Analysis of modes in a freestanding microsquare resonator by 3-D finite-difference time-domain simulation,” IEEE J. Quantum Electron. 41(7), 997-1001, 2005.

144.Y. Z. Huang, Q. Chen, W. H. Guo, and L. J. Yu, “Experimental observation of resonant modes in GaInAsP microsquare resonators,” IEEE Photon. Technol. Lett. 17(12), 2589-2591, 2005.

145.Q. Chen, Y. Z. Huang, W. H. Guo, and L. J. Yu, “Calculation of propagation loss in photonic crystal waveguides by FDTD technique and Padé approximation,” Opt. Comm. 248, 309-315, 2005.

146.Y. Z. Huang, Q. Chen, W. H. Guo, and L. J. Yu, “Application of Padé approximation in simulating photonic crystals,” Chin. J. Semicond. 26(7), 1281-1286, 2005.

147.C. Y. Jin, Y. Z. Huang, L. J. Yu, and S. L. Deng, “Numerical and theoretical analysis of the crosstalk in linear optical amplifiers,” IEEE J. Quantum Electron. 41(5), 636-641, 2005.

148.S. L. Deng, Y. Z. Huang, and L. J. Yu, “Intraband relaxation and its influences on quantum dot lasers,” Chin, Phys. Lett. 22(8), 2077-2080, 2005.

149.S. L. Deng, Y. Z. Huang, C. Y. Jin, and L. J. Yu, “Theoretical analysis of gain and threshold current,” Chin. J. Semicond. 26(10), 1898-1904, 2005.

150.Q. Y. Lu, X. H. Chen, W. H. Guo, L. J. Yu, Y. Z. Huang, J. Wang, and Y. Luo, “Mode characteristics of semiconductor equilateral triangle microcavities with side length of 5-20 μm,” IEEE Photon. Technol. Lett. 16(2), 359-361, 2004.

151.Y. Z. Huang, Q. Y. Lu, W. H. Guo, L. J. Yu, “Analysis of mode characteristics for equilateral triangle semiconductor microlasers with imperfect boundaries,” Proc. Optoelectron. 151(4), 202-204, 2004.

152.Y. Z. Huang, Y. H. Hu, Q. Chen, S. J. Wang, Y. Du, and Z. C. Fan, “Room-temperature continuous-wave electrically injected InP–GaInAsP equilateral-triangle-resonator lasers,” IEEE Photon. Technol. Lett. 19(13), 963-965, 2004.

153.W. H. Guo, Y. Z. Huang, Q. Y. Lu, and L. J. Yu, “Mode quality factor based on far-field emission for square resonators,” IEEE Photon. Technol. Lett. 16(2), 479-481, 2004.

154.W. H. Guo, Y. Z. Huang, Q. Y. Lu, and L. J. Yu, “Comparison of free spectral range and quality factor for two-dimensional square and circular microcavities,” Chin. Phys. Lett. 21(1), 79-80, 2004.

155.W. H. Guo, Q. Y. Lu, Y. Z. Huang, and L. J. Yu, “Fourier series expansion method for gain measurement from amplified spontaneous emission spectra of Fabry–Pérot semiconductor lasers,” J. Quantum Electron. 40(2), 123-129, 2004.

156.C. Y. Jin, Y. Z. Huang, L. J. Yu, and S. L. Deng, “Detailed model and investigation of gain saturation and carrier spatial hole burning for a semiconductor optical amplifier with gain clamping by a vertical laser field,” IEEE J. Quantum Electron. 40(2), pp.123-129, Feb. 2004.

157.H. B. Lei, L. J. Yu, Q. Y. Lu, W. H. Guo, C. L. Han, Y. Z. Huang, “Fabrication of 10×10 InGaAsP/InP array waveguide grating,” High Technol. Lett. 13(6), 49-50, 2003. (in Chinese)

158.Q. Y. Lu, X. H. Chen, W. H. Guo, L. J. Yu, Y. Z. Huang, J. Wang, and Y. Luo, “Experimental study of mode characteristics for equilateral triangle semiconductor microcavities,” Chin. Opt. Lett. 1(8), 472-474, 2003.

159.Q. Chen, Y. Z. Huang, W. H. Guo, and L. J. Yu, “Modulation of photonic bandgap and localized states by dielectric constant and filling factor in photonic crystals,” Chin. J. Semicond. 24(12), 1233-1237, 2003.

160.W. H. Guo, Y. Z. Huang, Q. Y. Lu, and L. J. Yu, “Whispering-gallery-like modes in square resonators,” IEEE J. Quantum Electron. 39(9), 1106-1110, 2003.

161.W. H. Guo, Y. Z. Huang, C. L. Han, and L. J. Yu, “Measurement of gain spectrum for Fabry–Pérot semiconductor lasers by the Fourier transform method with a deconvolution process,” IEEE J. Quantum Electron. 39(6), 716-721, 2003.

162.W. H. Guo, Q. Y. Lu, Y. Z. Huang, and L. J. Yu, “Measurement of gain spectrum for semiconductor lasers utilizing integrations of product of emission spectrum and a phase function over one mode interval,” IEEE Photon. Technol. Lett. 15(11), 1510-1512, 2003.

163.W. H. Guo, Y. Z. Huang, Q. Y. Lu, and L. J. Yu, “Modes in square resonators,” IEEE J. Quantum Electron. 39(12), 1563-1566, 2003.

164.C. L. Han, R. X. Liu, W. H. Guo, L. J. Yu, and Y. Z. Huang, “Measurement of cavity loss and quasi-Femi-level separation for Fabry-Perot semiconductor lasers,” Chin. J. Semicond. 24(8), 789-793, 2003.

165.C. Y. Jin, W. H. Guo, Y. Z. Huang, and L. J. Yu, “Photon iterative numerical technique for steady-state simulation of gain-clamped semiconductor optical amplifiers,” IEE Proc.-Optoelectron. 150(6), 503-507, 2003.

166.Y. Z. Huang, W. H. Guo, and Q. M. Wang, “Influence of output waveguide on mode qulity factor in semiconductor microlasers with an equilateral triangle resonator,” App. Phys. Lett. 77(22), 3511-3513, 2002.

167.Y. Z. Huang, W. H. Guo, and L. J. Yu, “Analysis of mode quality factors for equilateral triangle semiconductor microlasers with rough sidewalls,” Chin. Phys. Lett. 19(5), 674-676, 2002.

168.W. H. Guo and Y. Z. Huang, “Calculation of valence subband structure for strained quantum-well by plane wave expansion method within 6×Luttinger-Kohn model,” Chin. J. Semicond. 23(6), 577-581, 2002.

169.Y. Z. Huang and W. H. Guo, “Comparison of mode quality factors for equilateral triangular, square and rhombus optical micro-resonators,” Chin. J. Semicond. 22(2), 117-120, 2001.

170.Y. Z. Huang, W. H. Guo, and Q. M. Wang, “Analysis and numerical simulation of eigenmode characterisctics for semiconductor lasers with an equilateral triangle micro-resonator,” IEEE J. Quantum Electron. 37(1), 100-107, 2001.

171.Y. Z. Huang, W. H. Guo, L. J. Yu, and H. B. Lei, “Analysis of semiconductor microlasers with an equilateral triangle resonator by rate equations,” IEEE J. Quantum Electron. 37(10), 1259-1264, 2001.

172.Y. Z. Huang, W. H. Guo, and L. J. Yu, “Size limit and spontaneous emission factor for equilateral triangle semiconductor microlasers,” IEE Proc. Optoelectron. 148(5/6), 229-232, 2001.

173.W. H. Guo, W. J. Li, and Y. Z. Huang, “Computation of resonant frequencies and quality factors of cavities by FDTD technique and Padé approximation,” IEEE Microwave Wireless Compon. Lett. 11(5), 223-225, 2001.

174.Y. Z. Huang, “Comparison of modal gain and material gain for strong guiding slab waveguide,” IEE. Proc. Optoelectron. 148(3), 131-133, 2001.

175.W. H. Guo and Y. Z. Huang, and Q. M. Wang, “Resonant frequencies and quality factors for optical equlilateral triangle resonators calculated by FDTD technique and the Padé approximation,” IEEE Photon. Technol. Lett. 12(7), 813-815, 2000.

176.Y.Z. Huang, “Influence of reflection pase of air interface on mode characteristics of vertical-cavity surface-emitting lasers,” Acta Optica Sinica, 20(2), 181-185, 2000. (in Chinese)

177.Y. Z. Huang, “Influence of lateral propagating modes on laser output characteristics in selectively oxidized vertical-cavity surface-emitting lasers with double oxide layers,” J. Appl. Phys. 86, 3519-3524, 1999.

178.Y. Z. Huang, "Eigenmode confinement in equilateral triangle resonant optical cavities," Science Foundation in China 7(2), 70-73, 1999.

179.Y. Zhang, Z. Pan, Y. Du, Y. Z. Huang, and R. H. Wu, "Influence of process conditions of AlAs selective wet oxidation on oxidizing rate," Chinese J. Semicond., 20, 260-264, 1999.

180.Y. Z. Huang, “Effect of reflectivity at the interface of oxide layer on transverse mode control in oxide confined vertical-cavity surface-emitting lasers,” J. Appl. Phys. 83(7), 3769-3772, 1998.

181.Y. Zhang, Y. Z. Huang, and R. H. Wu, “Analysis of the noise in VCSEL using rate equation,” Acta Physica Sinica 47(2), 232-238, 1998. (in Chinese)

182.Y. Z. Huang, Z. Pan, and R. H. Wu, “Analysis of the optical confinement factor in semiconductor lasers,” J. Appl. Phys. 79, 3827-3830(1996)

183.R. H. Wu, W. Z. Gao, J. Zhao, H. L. Duan, S. M. Lin, Z. T. Zhong, Y. Z. Huang, and Q. M. Wang, “GaAs/GaAlAs multiquantum well reflectance light modulator and self electrooptic effect device,” Acta Photonica Sinica 24, 388-392, 1995. (in Chinese)

184.R. H. Wu, Z. Q. Zhou, Y. W. Lin, Z. Pan, Y. Z. Huang, C. Y. Li, Z .C. Niu, and W. Wang, “Sub-milliampere room temperature CW operation of InGaAs vertical-cavity surface-emittng lasers,” High Technol. Lett. 5(9), 24-26, 1995. (in Chinese)

185.Y. Z. Huang, “On the rate equations of semiconductor lasers for measuring spontaneous emission factor,” IEEE Photon. Technol. Lett. 7, 977-979, 1995.

186.M. A. Fisher, Y. Z. Huang, A. J. Dann, D. J. Elton, M. J. Harlow, S. D. Perrin, J .Reed, I. Reid, and M. J. Adams, “Pulsed electric operation of 1.5m vertical cavity surface emitting lasers,” IEEE Photon. Technol. Lett. 7, 608-610, 1995.

187.S. M. Lin, Y. Z. Huang, R. H. Wu, W. Z. Gao, and Z. Pan, “Comparison between the influences of layer thickness and AlAs mole fraction on vertical cavity surface-emitting lasers,” Fiber and Integrated Optics 12, 105-109, 1993.

188.Y. Z. Huang, S. M. Lin, and R. H. Wu, “Variation of stimulated emission with spontaneous emission spectrum in microcavity semiconductor lasers,” Superlattices and Microstructures 13, 267-270, 1993.

189.Y. Z. Huang and C. M. Wang, “Modeling of electron tunneling times in asymmetric double quantum wells,” Appl. Phys. A54, pp.308-310, 1992.

190.Y. Z. Huang and C. M. Wang, “Resonant tunneling, eigenvalue and energyband calculation for potential and periodic potential structures,” Appl. Phys. A54, 191-195, 1992.

191.Y. Z. Huang and C. M. Wang, “Comparisons of the phase times with tunneling times based on absorption probabilities,” J.Phys.: Condens. Matter 3, 5915-5919, 1991.

192.Y. Z. Huang, “Asymmetric gain induced by longtudinal spatial carrier burning in semiconductor lasers,” Electron. Lett. 26, 783-784, 1990.

193.C. Z. Guo and Y. Z. Huang, “Effects of dispersive relation and longitudinal coupled cavity on the mode spectral behaviour in semiconductor lasers,” Acta Physica Sinica 39, 1739-1744, 1990. (in Chinese)

194.C. Z. Guo and Y. Z. Huang, “Role of spontaneous emission factor in mode selection and linewidth compression in external cavity semiconductor lasers,” Chin. J. Semicond. 11, 654-658, 1990. (in Chinese)

195.C. Z. Guo and Y. Z. Huang, “Effect of the modal interaction on the spectral linewidth in the nearly single mode semiconductor lasers,” Acta Physica Sinica 39, 1075-1081, 1990. (in Chinese)

196.C. Z. Guo and Y. Z. Huang, “Control of the linewidth of semiconductor lasers by laterally coupled-cavity,” Acta Physica Sinica 38, 818-823,1989. (in Chinese)

197.C. Z. Guo and Y. Z. Huang, “Effect of nonlinear gain and waveguide structure on the linewidth of semiconductor lasers,” Acta Physica Sinica 38, 699-705,1989. (in Chinese)

198.C. Z. Guo and Y. Z. Huang, “Effect of carrier leakage over the heterobarrier on the To of InGaAsP semiconductor lasers,” Chin. J. Semicond. 8, 122-127, 1987 (in Chinese)

199.C. Z. Guo and Y. Z. Huang, “Effect of energyband structure on the optical gain spectra of InGaAsP quarternary semiconductors,” Chin. J. Semicond. 8, 49-60, 1987. (in Chinese)

Invited talks in international conference and symposium： 

1.Yong-Zhen Huang, Yong-Hong Hu, and Yue-De Yang, “Directional emission microlasers and mode coupling in microcavities,” International Nano Optoelectronics Workshop, 44-45, Beijing-Lanzhou, China, 2007. (invited)

2.Yong-Zhen Huang, Yue-De Yang, Shi-Jiang Wang, Kai-Jun Che, and Yun Du, “Directional emission whispering-gallery-mode semiconductor microcavity lasers,” International Nano Optoelectronics Workshop, Tokyo, Japan, 2008. (invited)

3.Yong-Zhen Huang, Yue-De Yang, Shi-Jiang Wang, Kai-Jun Che, and Wei Zhao, “Mode behavior in triangle and square microcavities,” Asia-Pacific Optical Communications, Proceedings of SPIE vol. 7135, art no. 713506, Hangzhou, China, 2008. (invited)

4.Yong-Zhen Huang, Yong-Hong Hu, Shi-Jiang Wang, Yue-De Yang, and Wei Zhao, “Directional emission triangle and square semiconductor microlasers,” The 6th Asia Pacific Laser Symposium, Nagoya, Japan, 2008. (invited)

5.Yong-Zhen Huang, Shi-Jiang Wang, Kai-Jun Che, Yue-De Yang, Jin-Long Xiao, Yong-Hong Hu, and Yun Du, “Room temperature continuous-wave electrically injected InGaAsP triangle and square microlasers,” International Conference of Optical Instrument and Technology, Proceedings of SPIE vol. 7158, art no.715806, Beijing, China, 2008. (invited)

6.Yong-Zhen Huang, Yue-De Yang, Shi-Jiang Wang, Jin-Long Xiao, and Yun Du, “InGaAsP/InP bistability triangle microlasers,” CLEO/Pacific Rim 2009-8th Pacific Rim Conference on Lasers and Electro-Optics, TuH3-2, Shanghai, China, 2009. (invited)

7.Yong-Zhen Huang, Yue-De Yang, Jian-Dong Lin, Kai-Jun Che, Shi-Jiang Wang, Jin-Long Xiao, and Yun Du, “Multiple-port directional emission whispering-gallery mode microlasers,” Conference on Laser Resonators, Microresonators, and Beam Control XIII: Proceedings of SPIE vol. 7913, art no. 79130V-1, San Francisco, America, 2011. (invited)

8.Yong-Zhen Huang, Jian-Dong Lin, Yue-De Yang, Qi-Feng Yao, Xiao-Meng Lv, Jin-Long Xiao, and Yun Du, “Unidirectional-emission single-mode whispering-gallery-mode microlasers,” Conference on Laser Resonators, Microresonators, and Beam Control XIV: Proceedings of SPIE vol. 8236, art no. 82360M-1, San Francisco, America, 2012. (invited)

9.Yong-Zhen Huang, Jian-Dong Lin, Xiao-Meng Lv, Qi-Feng Yao, Jin-Long Xiao, Yue-De Yang, and Yun Du, “Unidirectional micropillar lasers for on-chip optical interconnects,” Opto-Electronics and Communications Conference, 827-828, Busan, Korea, 2012. (invited)

10.Yong-Zhen Huang, Xiao-Meng Lv, Heng Long, Ling-Xiu Zou, Qi-Feng Yao, Yue-De Yang, Xin Jin, Ming-Ying Tang, Jin-Long Xiao, and Yun Du, “Far-field pattern simulation and measurement for unidirectional-emission circular microlasers,” Conference on Laser Resonators, Microresonators, and Beam Control XV: Proceedings of SPIE vol. 8600, art. no. 86001I-1, San Francisco, America, 2013. (invited)

11.Yong-Zhen Huang, Chu-Cai Guo, Jin-Long Xiao, and Yue-De Yang, “Mode selection for subwavelength Aluminum/Silica coated semiconductor circular nanoresonators,” Progress in Electromagnetics Research Symposium, Stockholm, Sweden, 2013. (invited)

12.Yong-Zhen Huang, “Wavelength control and thermal management for multi-wavelength microlaser array bonded on SOI waveguide,” Asia Communications and Photonics Conference, Shanghai, China, 2014. (invited)

13.Yong-Zhen Huang, Xiao-Meng Lv, Ling-Xiu Zou, Heng Long, Jin-Long Xiao, Yue-De Yang, and Yun Du, “Investigation on high speed directly modulated microcircular lasers,” Conference on Laser Resonators, Microresonators, and Beam Control XVI: Proceedings of SPIE vol. 8960, art no. 89600Z-1, San Francisco, America, 2014. (invited)

14.Yong-Zhen Huang, “Influence of external optical injection on small-signal modulation response for AlGaInAs/InP microring lasers,” Progress in Electromagnetics Research Symposium, Guangzhou, China, 2014. (invited)

15.Yong-Zhen Huang, Ling-Xiu Zou, Bo-Wen Liu, Yue-De Yang, Heng Long, Jin-Long Xiao, and Yun Du, “Dynamical characteristics of AlGaInAs/InP microdisk lasers subject to optical injection,” Conference on Laser Resonators, Microresonators, and Beam Control XVII: Proceedings of SPIE vol. 9343, art. no. 934308, San Francisco, America, 2015. (invited)

16.Yong-Zhen Huang, Ling-Xiu Zhou, Xiu-Wen Ma, Yue-De Yang, Jin-Long Xiao, and Yun Du, “Mode control for directional emission semiconductor microdisk and microring lasers,” 20^th Opto-Electronics and Communications Conference, Shanghai, China, 2015. (invited)

17.Yong-Zhen Huang, Ling-Xiu Zou, Xiu-Wen Ma, Yue-De Yang, Jin-Long Xiao, and Yun Du, “Nonlinear dynamics for integrated twin-microdisk laser with mutually optical injection,” Asia Communications and Photonics Conference, ASu3B.1, Hong Kong, China, 2015. (invited)

18.Yong-Zhen Huang, Ling-Xiu Zou, Xiu-Wen Ma, Yue-De Yang, Jin-Long Xiao, and Yun Du, “High speed modulation characteristics for semiconductor microdisk lasers,” 11^th Pacific Rim Conference on Lasers and Electro-Optics, Busan, Korea, 2015. (invited)

19.Huang Yong-Zhen, et al, “Degenerate mode control for hybrid spiral-ring microlasers to realize unidirectional emission from Si waveguide,” the 5^th Advances in Optoelectronics and Micro/nano-optics, Hangzhou, China, 2015. (invited)

20.Yong-Zhen Huang, Xiu-Wen Ma, Yue-De Yang, Jin-Long Xiao, and Yun Du, “Lasing characteristics of integrated lasers with whispering-gallery mode microresonator,” Conference on Smart Photonics and Optoelectronic Integrated Circuits XVIII, Proc. of SPIE, vol. 9751, art. no. 97510J, San Francisco, America, 2016. (invited)

21.Y. Z. Huang, H. Z. Weng, Z. X. Xiao, Y. D. Yang, J. L. Xiao, and Y. Du, “Semiconductor microlasers with curve-side polygon resonators,” 3A31, the 8th International Conference on Metamaterials, Photonic Crystals and Plasmonics (META 2017), 25-28 July 2017, Incheon Korea (invited)

22.Y. Z. Huang, H. Z. Weng, Y. D. Yang, J. L. Xiao, J. Y. Hn, M. L. Liao, and Y. Du, “Optical frequency comb generation by four-wave mixing with a seeding source of dual-mode microlasers,” 2-1F-1, CLEO-PR|OECC|PGC, 31 Jul-4 Aug 2017, Singapore (invited)

23.X. W. Ma, Y. Z. Huang, Y. D. Yang, and J. L. Xiao, “Optical memory based on bistable hybrid-cavity lasers,” the 6th Conference on Advances in Optoelectronics and Micro/nano-Optics (AOM 2018), 23-26 Apr 2017, Nanjing, China (invited)

24.Yong-Zhen Huang, Hai-Zhong Weng, Yue-De Yang, and Jin-Long Xiao, “Mode control for asymmetric deformed square microcavity lasers,” the 2^nd International Workshop on Asymmetric Microcavity and Wave Chaos, 17-20 May 2018, Fuzhou, China (invited)

25.Y. Z. Huang, F. L. Wang, Y. Z. Hao, Y. D. Yang, and J. L. Xiao, “Single mode and bistability coupled cavity semiconductor lasers,” Asia Communications and Photonics Conference, 26-29 Oct 2018, Hangzhou, China (invited)

26.Y. Z. Huang, “Circular-side polygonal microcavity semiconductor lasers,” W1J.1, Pacific Rim Conference on Lasers and Electro-Optics (CLEO-PR), 29 Jul-3 Aug 2018, Hong Kong, China (invited)

27.Y. Z. Huang, “Single mode operation and optical bistability for coupled-cavity semiconductor lasers”, 2018 Optoelectronics Global Conference (OGC 2018), 4-7 Sep 2018, Shenzhen, China (invited)

28.Y. Z. Huang, J. Y. Han, M. L. Liao, Y. D. Yang, and J. L. Xiao, “Microwave generations using single mode and dual-mode lasing microsquare lasers,” the 7^th Conference on Advances in Optoelectronics and Micro/nano-Optics (AOM 2018), 9-12 Oct 2018, Xi’an, China (invited)

29.Y. Z. Huang, “Square microcavity semiconductor lasers,” The 9^th International Multidisciplinary Conference on Optofluidics (IMCO2019), Sym6.5, 14-17 June 2019, Hong Kong, China (Keynote)

30.Y. Z. Huang, Y. Z. Hao, F. L. Wang, J. C. Liu, Y. D. Yang, and J. L. Xiao, “Hybrid-cavity semiconductor lasers for single mode operation and signal processing,” International Conference on Optical Communications and Networks, 5-8 Aug 2019, Huangshan, China (invited)

31.Y. Z. Huang, C. G. Ma, M. Tang, Z. X. Xiao, J. L. Xiao, Y. D. Yang, “Nonlinear dynamics for semiconductor microcavity lasers with internal mode injection effect,” 10^th International Conference on Materials for Advanced Technologies (ICMAT 2019), 23-28 June 2019, Singapore (invited)

32.Y. Z. Huang, Y. D. Yang, M. Tang, and J. L. Xiao, “Integrated semiconductor microcavity lasers,” Asia Communications and Photonics Conference, 2-5 Nov 2019, Chengdu, China (invited)

中文期刊论文：

[1]杨珂,杨跃德,肖金龙,黄永箴.Single-mode lasing in a coupled twin circular-side-octagon microcavity[J].Chinese Physics B,2022,31(09):215-221.

[2]Yang Ke,杨 珂,Yang Yue-De,杨 跃德,Xiao Jin-Long,肖 金龙,Huang Yong-Zhen,黄 永箴. Single-mode lasing in a coupled twin circular-side-octagon microcavity[J]. Chinese Physics B,2022,31(9).

[3]樊碤润,肖金龙,沈征征,郝友增,刘家辰,杨珂,杨跃德,黄永箴.1.65 μm square-FP coupled cavity semiconductor laser for methane gas detection[J].Chinese Optics Letters,2022,20(06):34-38.

[4]王婷,吴冀亮,马春光,黄勇涛,杨跃德,肖金龙,黄永箴.间距可调的双模正方形微腔激光器（特邀）[J].光子学报,2022,51(02):31-38.

[5]刘家辰,黄永箴,郝友增,杨珂,杨跃德,肖金龙.回音壁微腔激光器噪声特性数值模拟研究（特邀）[J].光子学报,2022,51(02):72-81.

[6]黄永箴,宁永强.“半导体激光材料及器件”专题导读[J].光子学报,2022,51(02):9-10.

[7]马春光,吴冀亮,肖金龙,黄勇涛,李亚理,杨跃德,黄永箴.Wideband chaos generation based on a dual-mode microsquare laser with optical feedback[J].Chinese Optics Letters,2021,19(11):49-53.

[8]樊碤润,肖金龙,杨跃德,郝友增,黄勇涛,黄永箴.回音壁微腔激光器电老化试验及寿命分析[J].中国激光,2022,49(06):78-84.

[9]黄永箴,郭霞,宋清海,张青.“半导体激光器”专题前言[J].中国激光,2020,47(07):9-10.

[10]黄勇涛,马春光,郝友增,肖金龙,杨跃德,黄永箴.正方形-FP耦合腔半导体激光器的激射及热特性研究[J].中国激光,2020,47(07):238-244.

[11]杨跃德,翁海中,郝友增,肖金龙,黄永箴.Square microcavity semiconductor lasers[J].Chinese Physics B,2018,27(11):180-189.

[12]吕晓萌,黄永箴,邹灵秀,杨跃德,肖金龙.半径5μm的定向输出圆盘形微腔激光器[J].中国激光,2017,44(09):75-80.

[13]姚齐峰,黄永箴,杨跃德,肖金龙.Analysis of mode characteristics for microcircular resonators confined by different metallic materials[J].Journal of Semiconductors,2016,37(12):55-62.

[14]陆日,许留洋,高欣,黄永箴,肖金龙,薄报学.电注入椭圆微腔半导体激光器热特性分析[J].中国激光,2016,43(04):48-53.

[15]隋少帅,唐明英,杨跃德,肖金龙,杜云,黄永箴.Single-mode hybrid Al Ga In As/Si octagonal-ring microlaser with stable output[J].Chinese Optics Letters,2016,14(03):59-62.

[16]杨跃德,隋少帅,唐明英,肖金龙,杜云,黄永箴.介质辅助键合Ⅲ-Ⅴ/硅基混合集成金属限制激光器[J].激光与光电子学进展,2014,51(11):94-99.

[17]黄永箴.Si基光子学专栏序言[J].激光与光电子学进展,2014,51(11):2.

[18]黄永箴,林建东,姚齐峰,吕晓萌,杨跃德,肖金龙,杜云.AlGaInAs/InP coupled-circular microlasers[J].Chinese Optics Letters,2012,10(09):49-51.

[19]王加贤,李俊杰,吴文广,黄永箴.耦合微盘及带输出波导的单微盘腔的耦合模式特性[J].光学学报,2011,31(01):81-86.

[20]曲连杰,杨跃德,黄永箴.光子晶体波导慢光特性研究[J].光学学报,2011,31(01):180-185.

[21]郭浩,吴评,于天宝,廖清华,刘念华,黄永箴.一种新型的光子晶体偏振光分束器的设计[J].物理学报,2010,59(08):5547-5552.

[22]王世君,黄永箴.基于SOI结构的1×8阵列上下载微环滤波器[J].光电子.激光,2010,21(08):1125-1128.DOI:10.16136/j.joel.2010.08.021.

[23]郭浩,方利广,吴小华,于天宝,廖清华,黄永箴.光子晶体环形谐振腔异质结构超微多路光分束器[J].光子学报,2010,39(07):1198-1202.

[24]吴文广,王加贤,黄永箴.Analysis of mode characteristics for hexagonal resonator lasers[J].Optoelectronics Letters,2010,6(04):256-260.

[25]黄永箴,杨跃德,王世江,肖金龙,车凯军,杜云.适于光子集成及光互连的回音壁微腔半导体激光器[J].中国科学:技术科学,2010,40(05):546-551.

[26]郭浩,吴评,于天宝,廖清华,刘念华,黄永箴.光子晶体环形谐振腔大角度超微多路光分束器的设计[J].光学学报,2010,30(05):1501-1505.

[27]杨跃德,王世江,黄永箴.Investigation of mode radiation loss for microdisk resonators with pedestals by FDTD technique[J].Chinese Optics Letters,2010,8(05):502-504.

[28]朱桂新,于天宝,陈淑文,廖清华,刘念华,黄永箴.一种新型光子晶体波导定向耦合型超微偏振光分束器[J].光子学报,2010,39(03):450-454.

[29]黄永箴,王世江,杨跃德,肖金龙,胡永红,杜云.半导体微腔双稳态激光器[J].激光与光电子学进展,2010,47(03):9.

[30]黄永箴,王世江,杨跃德,肖金龙.可集成的高速双稳态半导体激光器[J].激光与光电子学进展,2009,46(11):102-104.

[31]李敬,黄永箴,肖金龙,杜云,樊中朝.红光GaInP/AlGaInP正方形微腔激光器[J].光电子.激光,2009,20(10):1278-1281.

[32]陈淑文,胡萍,于天宝,廖清华,黄永箴.基于杂质带的光子晶体矩形波形滤波器的实现[J].光子学报,2009,38(10):2588-2592.

[33]陈淑文,朱桂新,于天宝,廖清华,刘念华,黄永箴.光子晶体波导定向耦合型1×3光分束器[J].光学学报,2009,29(10):2898-2904.

[34]胡淑娟,陈淑文,吴评,廖清华,黄永箴.定向耦合型超微多路光分束器的设计[J].光通信研究,2009(02):57-60.DOI:10.13756/j.gtxyj.2009.02.004.

[35]朱桂新,于天宝,陈淑文,石哲,胡淑娟,赖珍荃,廖清华,黄永箴.一种实现光子晶体波导定向耦合型多路光均分的新方法[J].物理学报,2009,58(02):1014-1019.

[36]黄永箴,车凯军,杨跃德,王世江,杜云.InGaAsP/InP正方形微腔激光器[J].激光与光电子学进展,2009,46(02):16.

[37]黄永箴,杨跃德,车凯军,王世江,杜云.平面工艺制作的定向输出微腔半导体激光器[J].激光与光电子学进展,2009,46(02):46-48.

[38]赵伟,黄永箴.Analysis of directional emission in square resonator lasers with an output waveguide[J].Chinese Optics Letters,2007(08):463-465.

[39]于丽娟,赵洪泉,杜云,李敬,黄永箴.硅基键合InP-InGaAsP量子阱连续激光器的研制[J].半导体学报,2007(07):1117-1120.

[40]刘戬,胡永红,张尚剑,谢亮,黄永箴,祝宁华.直接扣除法测量半导体光放大器频率响应[J].光学学报,2007(05):871-874.

[41]肖金龙,黄永箴,杜云,赵欢,倪海桥,牛智川. Gain Measurement and Anomalous Decrease of Peak Gain at Long Wavelength for InAs/GaAs Quantum-Dot Lasers[J]. 中国物理快报：英文版,2007,24(10).

[42]黄永箴,胡永红,于丽娟,陈沁,谭满清,马骁宇.1550nm偏振不灵敏半导体光放大器的研制[J].光电子·激光,2006(10):1157-1160.

[43]刘玉敏,俞重远,杨红波,黄永箴.InAs/GaAs透镜形量子点超晶格材料的纵向和横向周期对应变场分布的影响[J].物理学报,2006(10):5023-5029.

[44]胡萍,谈振兴,廖清华,黄永箴.一维对称光子晶体的简正耦合模(英文)[J].发光学报,2006(03):291-295.

[45]于丽娟,赵洪泉,杜云,黄永箴.键合法制备硅基1.55μmInP-InGaAsP量子阱激光器[J].半导体学报,2006(04):741-743.

[46]封强,俞重远,刘玉敏,杨红波,黄永箴.运用解析方法分析量子点的应力应变分布[J].北京邮电大学学报,2006(02):74-77.

[47]刘玉敏,俞重远,杨红波,黄永箴.GaN/AlN自组织平顶金字塔量子点的应变场分布[J].光电子·激光,2006(04):381-385.

[48]李德尧,黄永箴,张书明,种明,叶晓军,朱建军,赵德刚,陈良惠,杨辉,梁骏吾.脊形InGaN激光器的温度分布及其对器件特性的影响(英文)[J].半导体学报,2006(03):499-505.

[49]刘玉敏,俞重远,杨红波,黄永箴.应变自组织量子点的几何形态对应变场分布的影响[J].半导体学报,2005(12):2355-2362.

[50]邓盛凌,黄永箴,金潮渊,于丽娟.GaAs基长波长量子点激光器增益和阈值电流密度的理论分析(英文)[J].半导体学报,2005(10):1898-1904.

[51]刘玉敏,俞重远,杨红波,黄永箴.异质外延自组织量子点弹性应变场分布的研究[J].功能材料,2005(08):125-128.

[52]黄永箴,陈沁,国伟华,于丽娟.Padé近似在光子晶体模拟中的应用(英文)[J].半导体学报,2005(07):1281-1286.

[53]刘玉敏,俞重远,杨红波,黄永箴.有限元法分析透镜形自组织生长量子点的弹性应变场分布(英文)[J].半导体学报,2005(07):1317-1322.

[54]刘超,金潮渊,黄永箴,祝宁华.基于SOA的交叉增益调制中探测光能量的数值分析[J].半导体学报,2005(04):812-815.

[55]杨红波,俞重远,刘玉敏,黄永箴.影响半导体量子点生长因素的分析[J].人工晶体学报,2004(06):1018-1021.DOI:10.16553/j.cnki.issn1000-985x.2004.06.031.

[56]杨红波,俞重远,刘玉敏,黄永箴.半导体量子点内弹性应变能的研究(英文)[J].人工晶体学报,2004(04):531-534.DOI:10.16553/j.cnki.issn1000-985x.2004.04.014.

[57]黄永箴,国伟华.正三角形及正方形微光学腔模式特性研究[J].物理,2004(07):515-518.

[58]刘瑞东,于丽娟,芦秀玲,黄永箴,张福甲.(111)AInP衬底上MOCVD外延InGaAsP的表面形貌和光学特性[J].液晶与显示,2004(02):87-91.

[59]金潮渊,黄永箴.增益钳制半导体光放大器波长转换的研究[J].半导体光电,2004(01):29-31+52.DOI:10.16818/j.issn1001-5868.2004.01.009.

[60]国伟华,黄永箴,陆巧银,于丽娟. Comparison of Free Spectral Range and Quality Factor for Two-Dimensional Square and Circular Microcavities[J]. 中国物理快报：英文版,2004,21(1).

[61]陈沁,黄永箴,国伟华,于丽娟.介电常数对比和填充率对光子晶体中光子禁带和局域态的调节(英文)[J].半导体学报,2003(12):1233-1238.

[62]于丽娟,金潮渊,芦秀玲,黄永箴.1.55μm偏振不灵敏光放大器结构材料的生长[J].半导体光电,2003(04):274-275.DOI:10.16818/j.issn1001-5868.2003.04.017.

[63]陆巧银,陈晓红,国伟华,于丽娟,黄永箴,王建,罗毅.Experimental study of mode characteristics for equilateral triangle semiconductor microcavities[J].Chinese Optics Letters,2003(08):472-474.

[64]韩春林,刘瑞喜,国伟华,于丽娟,黄永箴.FP腔半导体激光器的腔内损耗和准费米能级差的测量(英文)[J].半导体学报,2003(08):789-793.

[65]黄黎蓉,李含辉,胡振华,黄永箴,黄德修.抗反膜设计改善半导体光放大器偏振不灵敏性的理论研究[J].中国激光,2003(07):633-636.

[66]雷红兵,于丽娟,陆巧银,国伟华,韩春林,黄永箴.10×10InGaAsP/InP阵列波导光栅器件的研制[J].高技术通讯,2003(06):49-50.

[67]黄黎蓉,黄德修,黄永箴.双折射对基于半导体光放大器的干涉型器件性能影响的模拟分析研究[J].光学学报,2003(04):407-411.

[68]陈弘达,申荣铉,毛陆虹,唐君,梁琨,杜云,黄永箴,吴荣汉,冯军,柯锡明,刘欢艳,王志功.16信道0.35μmCMOS/VCSEL光发射模块(英文)[J].半导体学报,2003(03):245-249.

[69]国伟华,黄永箴.Calculati用6×6Luttinger-Kohn模型和平面波展开方法计算应变量子阱材料的价带结构(英文)[J].半导体学报,2002(06):577-581.

[70]黄永箴,国伟华,等. Analysis of Mode Quality Factors for Equilateral Triangle Semiconductor Microlasers with Rough Sidewalls[J]. 中国物理快报：英文版,2002,19(5).

[71]王莉,陈弘达,潘钟,黄永箴,吴荣汉.垂直腔面发射激光器的研究进展及其应用[J].飞通光电子技术,2001(03):127-132.

[72]王莉,陈弘达,潘钟,黄永箴,吴荣汉.垂直腔面发射激光器的研究开发现状及其应用[J].高技术通讯,2001(04):104-108.

[73]邓晖,陈弘达,梁琨,杜云,唐君,黄永箴,潘钟,马骁宇,吴荣汉,王启明.InGaAs/GaAs多量子阱SEED设计和特性研究[J].光电子·激光,2001(03):222-224.

[74]邓晖,陈弘达,梁琨,杜云,唐君,黄永箴,潘钟,马晓宇,吴荣汉,王启明.InGaAs/GaAs多量子阱 SEED面阵结构特性与设计(英文)[J].半导体学报,2001(02):113-116.

[75]黄永箴,国伟华.等边三角形、正方形和平行四边形微光学谐振腔品质因子的比较(英文)[J].半导体学报,2001(02):117-120.

[76]黄永箴,国伟华. Comparison of Mode Quality Factors for Equilateral Triangular,Square and Rhombus Optical Micro-Resonators[J]. 半导体学报,2001(2).

[77]郭震宁,黄永箴,郭亨群,李世忱,王启明.a-SiO_x∶H/a-SiO_y∶H多层薄膜微结构的退火行为[J].半导体学报,2000(06):576-579.

[78]庄婉如,郑有炓,朱顺明,刘夏冰,黄永箴.光电导型混晶Si_1-xGe_x波导探测器[J].高技术通讯,2000(05):39-42.

[79]陈弘达,曾庆明,李献杰,陈志标,杜云,周革,华锋,黄永箴,吴荣汉.微光电子集成灵巧象素器件[J].光电子·激光,2000(02):111-113.

[80]陈弘达,陈志标,杜云,黄永箴,吴荣汉.多量子阱光开关器件的激子吸收及光调制特性[J].光电子·激光,2000(02):143-146.

[81]黄永箴.垂直腔面发射激光器中顶层相位对模式特性的影响[J].光学学报,2000(02):38-42.

[82]张益,潘钟,杜云,黄永箴,吴荣汉.AlAs选择性湿氮氧化的工艺条件对氧化速率的影响[J].半导体学报,1999(03):260-264.

[83]张益,黄永箴,吴荣汉.用速率方程分析垂直腔面发射激光器的噪声[J].物理学报,1998(02):57-63.

[84]吴荣汉,高文智,赵军,段海龙,林世鸣,钟战天,黄永箴,王启明.GaAs／GaAlAs多量子阱反射型光调制器及自电光效应器件[J].光子学报,1995(05):388-392.

[85]吴荣汉,周增圻,林耀望,潘钟,黄永箴,李朝勇,牛智川,王圩.亚毫安室温连续工作InGaAs垂直腔面发射激光器[J].高技术通讯,1995(09):24-26.

[86]林世鸣,吴荣汉,黄永箴,潘钟,高洪海,王启明,段海龙,高文智,罗丽萍,王立轩.GaAs／GaAlAs低阈值垂直腔面发射激光器[J].高技术通讯,1994(10):11-13.

[87]郭长志,黄永箴.色散关系和纵向耦合腔(C~3)对半导体激光器的模谱行为的影响[J].物理学报,1990(11):1739-1744.

[88]郭长志,黄永箴.自发发射因子在外腔半导体激光器的模式选择和线宽压缩过程中的作用[J].半导体学报,1990(09):654-658.

[89]郭长志,黄永箴.近单模半导体激光器中模式间相互作用对光谱线宽的影响[J].物理学报,1990(07):1075-1081.

[90]郭长志,黄永箴.非线性增益和波导结构对半导体激光器的谱线宽度的作用[J].物理学报,1989(05):699-705.

[91]郭长志,黄永箴.平行耦合腔波导对半导体激光器谱线宽度的控制作用[J].物理学报,1989(05):818-823.

[92]郭长志,黄永箴.异质势垒载流子泄漏对InGaAsP半导体激光器阈值温度关系的影响[J].半导体学报,1987(02):122-129.

[93]郭长志,黄永箴.能带结构对InGaAsP半导体光增益谱的影响[J].半导体学报,1987(01):49-60.

会议论文：

[1]金鑫; 黄永箴. 内径分布有部分光栅的圆环微腔激光器[C].全国第17次光纤通信暨第18届集成光学学术会议——无源、有源光器件和光子集成回路.2015:2-8.

荣誉奖励：

1．2020年半导体微腔激光器的模式调控及应用获得中国光学学会光学科技奖一等奖

2．2019年中国科学院大学朱李月华优秀教师奖

3．2018年微腔光子学学术研讨会上获得 “微腔光学成就奖”

4．研究成果入选《激光与光电子学进展》杂志评选的2008、2009和2010年度中国光学重要成果。

5．获得2009年国防科学技术进步二等奖和2019年（部委级）科学技术委员会科学技术进步奖一等奖

6．获得2005、2007、2015和2018年中科院优秀研究生指导教师奖

7．2006年中科院研究生院优秀教师，2008年中科院宝洁优秀研究生导师奖

8．培养的博士获得2005、2007，2015和2018年中科院优秀博士论文，以及2008年全国百篇优秀博士论文。

9．2004年获得国务院政府特殊津贴

10．2002年获得国家杰出青年科学基金

科技创新与品牌报道：

光子集成技术的基础：微腔激光器的研究

——访中科院半导体所集成光电子学国家重点联合实验室半导体所实验区主任黄永箴教授

光子集成芯片集成多种不同功能的光电子器件，既蕴含丰富的物理内涵，又有广阔的应用发展前景。可以预言，光子集成和光子学技术的发展将会是继微电子之后信息高科技的又一次巨大历史飞跃。基于这一前景，本刊记者专程采访了中科院半导体所光电子学专家黄永箴教授。

记者：在几何微腔激光器实验的研究方面，我国在国际上处于一个什么样的水平？您能为我们展望一下未来这个领域的研究方向和应用前景吗？

黄永箴：在定向输出回音壁微腔激光器的研制上，我们处于国际领先水平。但由于采用普通的光刻技术，我们只研制出尺度在10微米的微腔激光器，而且所研制的各种器件基本处于概念验证阶段，还没有实现性能的优化。我们从正三角形和正方形微腔激光器做到了主流的圆形微腔半导体激光器，但我们的圆形微腔激光器是可以直接与输出波导相连的，与前人的工作相比进了一步，特别适于光子集成。与金属相关的表面等离子体激元纳激光器是目前国际研究热点。数值模拟表明定向输出回音壁微腔激光器也可以做到尺度在微米量级，只要把器件的功耗降下来，这种器件在未来的光子集成、光互连、光存储和光信息处理方面具有重要的应用价值。

今天，集成电路芯片已经进入了人们日常生活的各个方面，极大地改善了人们的生活质量。具有极低阈值电流并可采用平面工艺制作的微腔激光器将是光子集成回路的理想光源，人们希望光子集成回路芯片将来也能像现在的集成电路一样改变世界的面貌；另一方面，随着信息技术的发展，微电子芯片间以及芯片内数据传输所需带宽飞速增长。目前数据传输还主要依靠传统的电互连，但其所需能量往往与距离成正比，将来高性能的计算芯片要求的数据带宽可能超过电互连的极限。光通信技术的能耗及带宽优势促使光互连不断在更短距离的数据传输上代替电互连。研究低功耗小体积的微腔激光器及微光探测器，并将其应用在光互连中对于信息技术发展有着重要意义，同时也符合绿色信息网络发展的需要。

在利用晶体材料解理面形成的法帕腔半导体激光器中，垂直于解理面模式光线的反射系数只有30%左右。但在圆形谐振腔中，以大于全反射临界角入射到界面上的模式光线可以完全限制在腔中。在上世纪90年代初，贝尔实验室首先研制出圆形的微盘激光器，后来日本人可以说把圆盘激光器推向了极致，他们研制出的圆盘激光器的半径甚至比激光波长还小。但是圆对称的微盘激光器没有定向的激光输出限制了这种激光器的可能应用，如何实现微腔激光器的定向输出引起人们极大的重视。人们往往通过局部破坏圆盘的对称性、圆盘的整体变形、以及与输出波导的消逝波耦合来实现微盘激光器定向激光输出。利用变形圆盘实现定向输出是人们研究最多的一种解决方案，而且变形圆盘中模式光线往往具有混沌特性，物理现象非常丰富，吸引了许多研究人员的注意。

记者：我们了解到您在国际上率先研究得出正三角形和正方形光学微腔的模式解析场分布，并研制出正三角形和正方形光学微腔半导体激光器，可以说是业内首屈一指的专家。能否为我们介绍一下这项成果？

黄永箴：我认为从微腔上直接连接一输出波导是实现定向输出微腔激光器的最简单方案，而且也适合应用到集成光学回路上。但一般认为模式光线绕圆形微腔一周就会散射到连接的输出波导，微腔模式寿命将大大降低，不易于实现激射。我们首先研究得出正三角形和正方形微腔的模式场分布和模式波长，发现其边界模式场分布的包络不像圆形微腔一样是均匀分布的，而是受横模场分布的调控。在场分布弱的地方连接输出波导，可以在保证模式长寿命的条件下实现定向输出。根据模式特性的研究成果，我们首次利用（100）面生长的普通半导体激光器芯片研制成功室温连续激射的正三角形和正方形微腔激光器。最近，我们还发现在圆形微腔中连接一输出波导，对称性的破缺造成模式耦合现象。利用这种耦合模，我们研制出直接连接输出波导的圆形微腔激光器。另外，我们还研制出连接两个输出波导的正方形微腔激光器，《Compound Semiconductors》杂志以《光子集成回路能受益于正方形微腔激光器》为题报道了我们所发表的论文。

记者：请简要介绍一下您的求学经历？您为什么要选择光学微腔的模式特性作为您的研究方向？

黄永箴：我1979年从福建泉州六中考到北京大学物理系，1989年拿到博士学位，然后到中科院半导体所工作。1994年作为访问学者在英国电信实验室呆了一年，经历非常简单。

进入半导体所前10年主要是参加课题组的研究工作，主要是属于跟踪性质的高技术研究项目。从1999年开始独立从事研究工作，面临的最大问题就是选择什么研究方向。当时定向输出微腔激光器是光电子器件研究的热点问题，而对变形圆盘微腔的研究最多，考虑到集成光学是我们实验室的主攻方向，集成光学需要微小的光学器件，而且可用平面工艺制作的连接输出波导的微腔激光器应该是最适合集成的。为此，我从几何光学的光线传播分析正三角形可能适合制作定向输出的微腔激光器。但当时我们所的工艺条件有限，所以先从光学微腔的模式特性分析和数值模拟出发开展研究。在刚有想法时能得到国家自然科学基金的支持，而且在2002年得到了国家杰出青年科学基金的资助，使得我可以以微腔激光器研究作为主要的研究课题专心开展工作。

记者：科学研究成果的取得离不开自主创新精神。近几年来我国一直在大力提倡建设创新型国家，您在实际的研究工作中，对自主创新有哪些认识和体会？结合您的研究经验，您认为怎样才能做到自主创新?

黄永箴：应该说我从选择微腔激光器的研究开始就走上一条自主创新的道路。我只是选择了定向输出微腔激光器这个需求，而没有跟随当时国际上的研究热点—变形圆盘激光器，但完全创新还是很难的。开始研究不久，实验室一位研究人员就跟我说IBM在1964年就发表过正三角腔激光器的论文，后来发现日本的NTT在几年前也研制了正三角腔激光器。但他们的器件都是利用（111）晶面上材料用解理或选择生长方法制作的，而我们是要用平面工艺在通用的（100）晶面上半导体材料制作正三角腔激光器。因此，我觉得我的方案还是创新的，并一直坚持下来。

我选择的不是一个大的热点，但是一个具有重要应用价值，而且还很不成熟的研究课题，可以说有点幸运。不断获得新的研究成果也使我可以一直坚持做下来，我们已经在IEEE系列刊物上发表了20篇有关正三角形和正方形微腔的研究论文。我跟家人笑说我就是个农民教授，农民的选择比较单纯，也能一直坚持下来。

记者：您除了自己做学术研究之外，也带博士生，而且您的学生屡次获奖，您在人才培养和学术团队建设方面有哪些成功的经验？

黄永箴：我带研究生与做学术研究是结合在一起的。我的第一个研究生国伟华是1999年开始进实验室工作的，他为我们实验室的研究特别是后来的研究生起了很好的带头作用。他获得了中国科学院院长奖和优秀博士论文。我带的从事光学微腔激光器研究的研究生已有5人次获得中国科学院院长奖（今年两个），两次获得中国科学院优秀博士论文，和一次全国百篇优秀博士论文。对于研究生，我管得不是太多，主要是给他们选定研究方向，并尽可能的提供条件。所安排的研究课题较少有直接的器件性能指标，相对宽松的环境使研究生有较大的自由，但我也要经常修正他们的研究想法，什么时候该放手让研究生去做、什么时候该叫停是一个很难的选择。研究生没有觉得有太大的压力，还常给我建议要怎么管理。我的办公室就在研究生学习室的对面，我几乎每天都要多次到他们的学习室打水喝，有问题就可以讨论。选择一个适合自己、有发展前景或重要应用价值的研究课题是非常重要的。这10来年的工作，我们相当于是要把一个比较小的研究课题做大。我没什么特别的兴趣爱好，小的时候喜欢画画，也就是对着图画“照猫画猫”。上大学后基本就不画了。中国有句俗话叫“照猫画虎”，有时我开玩笑说我们搞研究不能“照虎画猫”。

黄永箴，分别于1983年、1986年和1989年在北京大学物理系获得学士、硕士和博士学位，并于1989年进入中科院半导体研究所工作。分别获得杰出青年基金、**计划、“863”、“973”等基金支持。现为中科院半导体所光电子研发中心主任、集成光电子学国家重点联合实验室学术委员会主任、中科院半导体所学术委员会副主任。重点研究方向是光学微腔的模式特性并研制微腔激光器。过去几年系统研究了适用于光子集成的定向输出微腔半导体激光器，在国际上率先研究得出正三角形和正方形光学微腔的模式解析场分布，并研制出正三角形和正方形光学微腔半导体激光器，以及带输出波导的圆形微腔半导体激光器。连续多年获得中科院优秀研究生指导教师奖。他所培养的博士获得全国百篇优秀博士论文一次、中科院优秀博士论文两次和中科院院长优秀奖三次。

来源：《科技创新与品牌》2010年第8期

 

 

2010年6月Compound Semiconductor杂志以”光子集成回路可能受益于正方形激光器”为题报道了我们研制出第一个具有对角输出端口正方形激光器. 

 

 

2010年6月Electronics Letters的中国论文重印集以”发展中的微型激光器”为题介绍了我们的微腔激光器研究成果.