清華大學

清華大學電子工程系信息光電子研究所導師信息

黃翊東    博士 教授

羅姆樓2-103A，中國北京市清華大學電子工程系 100084

電話： +86-10-62797396

傳真：+86-10-62770317

電子郵箱： yidonghuang@tsinghua.edu.cn

實驗室主頁：http://www.nano-oelab.net

教育背景1994年畢業(yè)于清華大學電子工程系(博士學位)。1991年至1993年作為聯(lián)合培養(yǎng)博士生赴日本東京工業(yè)大學留學,在此期間從事了應變量子阱激光器及放大器增益特性的研究,獲得優(yōu)秀博士論文獎。

工作履歷1994年成為NEC光-無線器件研究所的特聘研究員,從事用于光纖通信領(lǐng)域的1.3及1.5微米DFB激光器的研究開發(fā)工作。于1997年獲得NEC一等研究功績獎，2003年獲得NEC二等研究功績獎。

2003年7月作為清華大學“百人計劃”引進人才，到清華大學電子工程系任教，2005年2月被聘為教育部長江學者特聘教授，2007年被評為“新世紀百千萬人才工程”國家級人選。在2007年至2012年期間擔任電子工程系副系主任，并于2013年起擔任系主任。

學術(shù)兼職現(xiàn)為美國電子電機工程學會（IEEE）的會員，《電子學報》編委，中國計量科學研究院計量科學咨詢委員會委員。

研究概況目前承擔了國家自然科學基金重點項目、973項目以及多項國際合作項目，致力于納結(jié)構(gòu)光電子學領(lǐng)域的研究，她的研究小組在光子晶體、表面等離子體波導器件以及量子通信光源的研究中取得重要進展，發(fā)表論文200余篇。

學術(shù)成果期刊論文

[1] Y. Huang, K. Komori, and S. Arai, "Reduction of noise figure in semiconductor laser amplifiers with Ga1-xInxAs/GaInAsP/InP strained quantum well structure", IEEE J. Quantum Electron., vol. 29, no. 12, pp. 2950-2956, 1993.

[2] Y. Huang, S. Arai, and K. Komori, "Theoretical linewidth enhancement factor of Ga1-xInxAs/GaInAsP/InP strained quantum well structures", IEEE Photo. Tech. Lett., vol.5, no.2, pp.142-145, 1993.

[3] K. Kudo, Y. Nagashima, S. Tamura, S. Arai, and Y. Huang, "Ga1-xInxAs/GaInAsP/InP tensile-strained single quantum-well lasers with 70-nm period wire active region", IEEE Photo.Tech. Lett., vol. 5, no. 8, pp. 864-867, 1993.

[4] Y. Huang, K. Komori, and S. Arai, "Theoretical noise characteristics of semiconductor laser amplifiers with Ga1-xInxAs/GaInAsP/InP strained quantum well structure", IEICE Technical Report, OQE92-150, 1993.

[5] Y. Huang, K. Komori, K. Kudo, S. E. Yumin, and S. Arai, "Ga1-xInxAs/GaInAsP/InP tensile-strained quantum well semiconductor laser amplifiers with tapered waveguide structures", IEICE Technical Report, OCS93-20, 1993.

[6] K. Komori, Y. Huang, S.El Yumin, and S. Arai, "Saturation characteristics and optical coupling of tapered-waveguide traveling wave semiconductor laser amplifier (TTW-SLA)", IEICE Technical Report, OQE93-64, 1993.

[7] Y. Huang, S. Arai, and K. Komori, "Effect of Strain on threshold current of Ga1-xInxAs/GaInAsP/InP strained quantum well lasers", Nat. Conv. Rec. of IEICE Japan, C-158, 1993, Japan.

[8] Y. Huang, K. Komori, K. Komori, and S. Arai, "Saturation characteristics of Ga1-xInxAs/GaInAsP/InP tensile-strained QW semiconductor laser amplifiers with tapered waveguide structures", IEEE J. Quantum Electron., vol. 30, no. 9, pp. 2034-2039, 1994.

[9] Y. Huang, H. Yamada, Y. Sasaki, T. Torikai, and T. Uji, "Gain characteristics of 1.3？m compressively strained MQW lasers at high temperature", NEC Research & Development, vol. 36, no. 4, pp. 479-484, 1995.

[10] Y. Huang, H. Yamada, T. Okuda, T. Torikai, and T. Uji, "External optical feedback resistant characteristics in partially-corrugated-waveguide laser diodes", Electron. Lett., vol. 32, no. 11, pp. 1008-1009, 1996.

[11] T. Okuda, Y. Huang, H. Yamada, Y. Sasaki, and T.Torikai, "Partially corrugated waveguide laser diodes for optical CATV network", IEICE Technical Report, OQE92-150, 1996.

[12] K. Shiba, T. Okuda, Y. Huang, H. Yamada, and T. Torikai, "External optical feedback resistant 622-Mb/s modulation of partially-corrugated-waveguide laser diodes over -40 to +85C", IEEE Photo. Tech. Lett., vol. 10, pp.872-874, 1998.

[13] T. Okuda, K. Shiba, Y. Huang, Y. Muroya, N. Suzuki, and T. Torikai, "High-yield partially corrugated waveguide laser diodes for optical networks", IEICE Technical Report, OPE98-13, 1998.

[14] Y. Huang, T.Okuda, K. Shiba, and T. Torikai, "Grating length dependence of external optica feedback resistant characteristics in PC-LDs", Nat. Conv. Rec. of IEICE Japan, c-4-32, 1998, Japan.

[15] Y. Huang, T. Okuda, K. Shiba, Y. Muroya, N. Suzuki, and K. Kobayashi, "External optical feedback resistant 2.5-Gb/s transmission of partially corrugated waveguide laser diodes over a -40 to 80 C temperature range", IEEE Photo. Tech. Lett., vol. 11, no. 11, pp. 1482-1484, 1999.

[16] Y. Huang, T. Okuda, K. Shiba, and T. Torikai, "High-yield external optical feedback resistant partially-corrugated-waveguide laser diodes", IEEE J. Quantum Electron., vol. 5, no. 3, pp. 435-441, 1999.

[17] Y. Huang, T. Okuda, K. Sato, Y. Muroya, T. Sasaki, and K. Kobayashi, "Low chirping ？/8 phase-shifted DFB-LDs under direct modulation", IEICE Technical Report, OPE2000-43, 2000.

[18] Y. Huang, T. Okuda, K. Sato, Y. Muroya, T. Sasaki, and K. Kobayashi, "Isolator-free 2.5-Gb/s, 80-km transmission by directly modulated ？/8 phase-shifted DFB-LDs under negative feedback effect of mirror loss", IEEE Photo. Tech. Lett., vol. 13, no. 3, pp. 245-247, 2001.

[19] Y.Huang, K. Sato, T. Okuda, N. Suzuki, S. Ae, Y. Muroya, K. Mori, T. Sasaki, and K. Kobayashi, "Low-chirp and external optical feedback resistant characteristics in ？/8 phase-shifted DFB-LDs under direct modulation", IEEE J. Quantum Electron. vol. 35, no. 11, pp. 1479-1484, 2002.

[20] Y. Zhong, X. Zhu, G. Song, Y. Huang, L. Chen, “Effect of metal contact's reflection on the effective coupling coefficient of second-order DFB laser diodes”, Microwave and Optical Tech. Lett., vol. 42, no. 4, pp. 339-342, 2004.

[21] Y. Zhong, X. Zhu, G. Song, Y. Huang, L. Chen, “Two-dimensional simulation of high-order laterally-coupled GaAs-AlGaAs DFB laser diodes”, Semiconductor Science and Technology, vol.19, pp. 971-974, 2004.

[22] *Y.Luo, W. Zhang, Y. Huang, J. Peng, J. Zhao "Wide-angle beam splitting using the positive-negative refraction in photonic crystals", Optics Lett., vol.29, no. 24, pp.2920-2923, 2004.

[23] *C. Li, Y. Huang, W. Zhang, Y. Ni, and J. Peng, “Amplification Properties of Erbium-doped Solid-core Photonic Bandgap Fibers”, IEEE Photo. Tech. Lett., vol. 17, no. 2, pp. 324-326, 2005.

[24] *X. Hu, Y. Huang, W. Zhang, D. Qing, Jiangde Peng, “Opposite Goos-Hänchen shifts for TE and TM beams at the interface associated with single negative materials”, Optics Lett., vol.30, no. 8, pp.899-901,2005.

[25] *J.Wang, Y. Huang, W. Zhang, J. Peng, "Reduction of refractive index contrast threshold for photonic band-gap in square lattices", Chin.Phys.Lett., vol.22, no.12, pp.3094-3096, 2005.

[26] Y. Huang, “Optoelectronic device in optical fiber communications”, (Invited Paper) Physics, vol. 34, no. 10, pp. 739-747, 2005.

[27] *C. Li, W. Zhang, Y. Huang, and J. Peng, “Numerical study on Bragg fibers for infrared applications”, J.of Infrared and Millimeter Waves, vol. 26, no. 6, pp. 893-904, 2005.

[28] *H. Zhao, Y. Huang, W. Zhang, J. Peng, “Simulation of active region for polarization-insensitive superluminescent diodes” Chin. Optic.Lett, vol. 4, no. 3, pp.181-183, 2006.

[29] *Z. Xin, Y. Huang, Z. Han, W. Zhang, J. Peng,, “Optimization Design of Superluminescent Diodes with RWG Structure for High Efficiency Coupling with SMFs”, Chinese J. of Semiconductors, vol. 27, no. 4, pp.113-117, 2006.

[30] *P. Wang, Y. Huang, W. Zhang, J. Peng, “Out-plane confinement with matching layer structure in quasi-3D photonic crystal waveguide” IEEE Photo. Tech. Lett., vol. 18, no. 11, pp. 1270-1272, 2006.

[31] *F. Li, Y. Huang, W. Zhang, J. Peng, “spatially inhomogeneous gain modufication in photonic crystals”, Chin.Phys.Lett., vol. 23, no.8, pp.2117-2120, 2006.

[32] *X. Hu, Y. Huang, Wei Zhang, Jiangde Peng, “Dominating radiative recombination in a Nano-porous silicon layer with a metal–rich Au(1-？)-SiO2(？) cermet waveguide”, Appl. Phys. Lett. vol. 89, no. 081112, 2006.

[33] W. Zhang, *L. Zhang, *L. Xiao, Y. Huang, J. Peng, “Microstructure- Fiber-Based Optical Parametric Amplification in Telecom Band with Ultra High Gain Slope”, Chinese Physics Letters,2006.

[34] W. Zhang, *L. Zhang, S. Chen, Q. Cai, Y. Huang, J. Peng,“Low Loss Splicing Experiment of High Nonlinearity Photonic Crystal Fiber and Single Mode Fiber”, China Laser,vol. 33, no. 10, pp. 1389-1392, 2006.

[35] *C. Lin, W. Zhang, Y. Huang, J. Peng, "Zero dispersion slow light with low leakage loss in defect Bragg Fiber”, Appl. Phys. Lett. vol. 90, no. 031109, 2007.

[36] *G. Xu, W. Zhang, Y. Huang, J. Peng, “Loss Characteristics of Single HE11 Mode Bragg Fiber”, IEEE J. Lightwave Tech.,vol. 25, no. 1, 2007.

[37] *Y. Rao, *F. Liu, Y. Huang, W. Zhang, J. Peng, ” Long Range Surface Plasmon Polariton Guided by Thin Metal Stripe”, Chin. Phys. Lett., vol. 24, 1626, 2007.

[38] *X. Mao, *J. Wang, Y. Huang, W. Zhang, J. Peng,.“Improving performance of photonic crystal couplers by suppressing mode power reservation” Chin.Phys.Lett., vol. 24, no. 2, pp.454-457, 2007.

[39] *F. Liu, *Y. Rao, Y. Huang, W. Zhang, J. Peng, “Coupling Between Long Range Surface Plasmon Polariton Mode and Dielectric Waveguide Mode”, Appl. Phys. Lett., 90, 141101, 2007.

[40] *F. Liu, Y. Huang, D. Ohnishi, W. Zhang, J. Peng, “Existence of Long Range Surface Plasmon Polariton Modes Guided by Thin Metal Films”, Chin. Phys. Lett., vol. 24, no.12, pp.3462-3464, 2007.

[41] *F. Liu, Y. Huang, D. Ohnishi, W. Zhang, J. Peng, “Hybrid three-arm coupler with long range surface plasmon polariton and dielectric waveguides”, Appl. Phys. Lett., 90, 241120, 2007.

[42] *C. Zhang, *X. Tang, *X. Mao, *K. Cui, *L. Cao, Y. Huang, W. Zhang, and J. Peng, “Design, Fabrication, and Measurement of Two Dimensional Photonic Crystal Slab Waveguides”, Chin.Phys.Lett., vol. 25, no. 3, pp.978-980, 2008.

[43] *K. Cui, Y. Huang, W. Zhang, and J. Peng, “Modified gain and mode characteristics in two-dimension photonic crystal waveguide with microcavity structure”, IEEE J. Lightwave Tech., vol. 26, pp. 1492-1497, 2008.

[44] *C. Lei, Y. Huang, X. Mao, F. Li, W. Zhang, J. Peng, “Fluid Sensor Based on Transmission Dip Caused by Mini Stop-Band in Photonic Crystal Slab”, Chin.Phys.Lett., vol. 25, no. 6, pp.2101-2103, 2008.

[45] *X. Mao, *D. Yao, *L. Zhao, Y. Huang, W. Zhang, J. Peng, “An integrative biochemical sensor based on contra-directional coupling PC-waveguides”, Chin.Phys.Lett., vol. 25, no. 1, pp.141-143, 2008.

[46] *X. Tang, Y. Huang, Y. Wang, K. Chen, W. Zhang, and J. Peng, “Tunable surface plasmons for emission enhancement of silicon nanocrystals using Ag-poor cermet layer”, Appl. Phys. Lett.. vol. 92, no. 25, pp.251116-1-3, 2008.

[47] Y. Huang, X. Mao, K. Cui, C. Zhang, L. Cao, W. Zhang and J. Peng, “Photonic crystal waveguides and their applications”, (Invited paper), Chin. Optical. Lett.. vol. 6, no. 10, pp.704-708, 2008.

[48] *F. Liu *R. Wan *Y. Li, Y. Huang Y. Miura, D. Ohnishi, and J. Peng, "Extremely high efficient coupling between long range surface plasmon polariton and dielectric waveguide mode", Applied Physics Letters, 95 (9): 91103-91104, 2009.

[49] *F. Liu, *R. Wan, Y. Huang, and J. Peng, "Refractive index dependence of the coupling characteristics between long-range surface-plasmon-polariton and dielectric waveguide modes", Optics Letters, 34 (17): 2697-2699, 2009.

[50] X. Feng, *W. Ke, *X. Tang, Y. Huang, W. Zhang, and J. Peng, “Numerical Solution of Surface Plasmon Polariton Mode Propagating on Spatially Periodic Metal-Dielectric Interface”, Journal of the Optical Society of America B, 26 (12): B11 - B20, 2009.

[51] *X. Mao, Y. Huang, *K. Cui, *C. Zhang, W. Zhang, and J. Peng, "Effects of structure parameters and structural deviations on the characteristics of photonic crystal directional couplers", IEEE Journal of Lightwave Technology, 27 (18): 4049-4054, 2009.

[52] *R. Wan, *L. Fang, and *T. Xuan, Y. Huang, and J. Peng, "Vertical coupling between short range surface plasmon polariton mode and dielectric waveguide mode", Applied Physics Letters, 94 (14): 141103-141104, 2009.

[53] *Q. Zhou, W. Zhang, J. Cheng, Y. Huang, and J. Peng, “Polarization-Entangled Bell States Generation Based on Birefringence in High Nonlinear Microstructure Fiber at 1.5？？m”, Optics Letters, 34 (15)：2706-2708, 2009.

[54] W. Wang, W. Zhang, and W. Xing, L. Shi, Y. Huang, and J. Peng, "A novel 3-D microcavity based on bragg fiber dual-tapers", IEEE Journal of Lightwave Technology, 27 (18): 4145-4150, 2009.

[55] W. Zhang, X. Feng, Y. Huang, and J. Peng, "Bi-directional dual-wavelength Brillouin lasing in a hybrid fiber ring cavity", Optics Communications, 282 (14): 2990-2994, 2009.

[56] Y. Wang, W. Zhang, Y. Huang, and J. Peng, "Stimulated Brillouin scattering slow light in high nonlinearity silica microstructure fiber", Optical Fiber Technology: Materials, Devices and Systems, 15 (1): 1-4, 2009.

[57] W. Zhang, Y. Wang, Y. Huang, and J. Peng, "Theoretical analysis of novel Brillouin scattering properties in photonic crystal fibers based on silica rod model", Acta Physica Sinica, 58 (3): 1731-1737, 2009.

[58] S. Zhang, W. Zhang, Q. Zhou, Y. Huang, and J. Peng, "Experimental Study on Preparation Efficiency of Microstructured-Fibre Based Heralded Single-Photon Source at 1.5？？m", Chinese Physics Letters, 26 (3): 034206, 2009.

[59] *C. Zhang, Y. Huang, and X. Mao, K. Cui, Y. Huang, W. Zhang, and J. Peng, "Slow light by two-dimensional photonic crystal waveguides", Chinese Physics Letters, 26 (7):74213-74216, 2009.

[60] *X. Mao, Y. Huang, W. Zhang and J. Peng, “Coupling between even- and odd-like modes in a single asymmetric photonic crystal waveguide”, (to be published in Applied Physics Letters)

[61] *K. Cui, Y. Huang, G. Zhang, Y. Li, X. Tang, X. Mao, Q. Zhao, W. Zhang, and J. Peng, “Temperature dependence of mini-stop band in double-slots photonic crystal waveguides”, Applied Physics Letters. 95, 191901, 2009.

精選會議論文

[1] Y. Huang, T. Okuda, K. Shiba and T. Torikai, "High yield external optical feedback resistant partially-corrugated-waveguide laser diode for isolator-free LD modules", IEEE International Semiconductor Laser Conference, TuE44, 1998, Japan.

[2] Y. Huang, K. Shiba, Y. Muruya, N. Suzuki, and T. Okuda, "Isolator-free 2.5 Gb/s, 45 km transmission characteristics in partially corrugated waveguide laser diodes from -40 to 80C under -14 dB external optical feedback," OFC'99, WH6, 1999, U.S.A..

[3] Y. Huang, T. Okuda, K. Sato, Y. Muroya, and K. Kobayashi, "Feedback effect of mirror loss in ？/8 phase-shifted DFB-LDs", APCC/OECC’99, C6S4-127, 1999, China.

[4] Y.Huang, T. Okuda, K. Sato, Y. Muroya, T. Sasaki, and Kenich Kobayashi, "External reflection resistant and low chirp 1.55？m ？/8 phase-shift DFB-LDs for 2.5-Gb/s directly modulated isolator-free uncooled long-distance optical transponders", (Invited paper) Photonics Asia, SPIE vol. 4913, pp.19-26, 2002, China.

[5] *K. Cui, Y. Huang, X. Mao, W. Zhang, J. Peng, “Optical gain of InGaAsP MQW with different photonic crystal waveguides”, IPRM’2007, PA32, 5121.

[6] *X. Tang, Y. Huang, W. Zhang, J. Peng, “Internal Quantum Efficiency Enhancement of Silicon Nanocrystals Using Doublelayer Au Film Surface-Plasmon Waveguide”, IPRM’2007, PA33, 5111, Japan.

[7] *Y. Wang, W. Zhang, Y. Huang, and J. Peng, “SBS Slow Light in High Nonlinearity Photonic Crystal Fiber”, OFC,JWA13, 2007, USA.

[8] Y. Huang, F. Liu, Y. Rao, R. Wan, D. Qu, W. Zhang, and J. Peng, “Low loss long range surface plasma polariton waveguides and their applications”, (Invited Paper), IC-PlANTS, 2008, Japan.

[9] Y. Huang, X. Mao, K. C., C. Zhang, L. Cao, W. Zhang, and J. Peng, “Passive and active performances of slab photonic crystal waveguides”, (invited paper), International Nano-Optoelectronics Workshop, pp.32-33, 2008.

[10] Y. Huang, X. Tang, Y. Wang, X. Feng, K. Chen, W. Zhang, and J. Peng, “Surface Plasmon Assisted Emission Enhancement for Silicon Nanocrystals”, (invited paper), Nat. Conv. Rec. of Japan Soc. Appl Phys., 2p-ZN-2, 2008, Japan.

[11] *F. Liu, *R. Wan, *Y. Rao, Y. Huang, W. Zhang, and J. Peng, “Polarization Splitter Based on Hybrid Coupler with Long Range Surface Plasmon Polariton and Dielectric Waveguide(s)”, OFC, OThG3, 2008.

[12] Q. Zhou, W. Zhang, S. Zhang, J. Cheng, Y. Huang, and J. Peng, “1.5 ？m Polarization Entangled Photon Pair Generation Based on Birefringence in Microstructure Fibers”, Optical Fiber Communications Conference (Optical Society of America, 2009), paper OWD6.