固定成员

张新亮教授

张新亮,男,博士,教授,博士生导师。1971年10月生于湖北省黄梅县,1992年在华中理工大学获学士学位,2001年6月在华中科技大学(华中理工大学)获物理电子学博士学位。先后入选武汉市青年晨光人才、教育部新世纪优秀人才、湖北省杰出青年基金、国家杰出青年基金、中组部万人计划创新领军人才、教育部长江学者特聘教授(2017)等计划,是美国光学学会Fellow。
在学术兼职方面,现任中国光学学会常务理事、湖北省仪器仪表学会理事长、国务院光学工程学科评议组成员和教育部”光电信息科学与工程”专业分教指委副主任,担任《Frontiers of Optoelectronics》期刊共主编,《Photonics Research》和《Photonics Journal》副编辑。在公共事务方面,2012年6月至2019年1月曾任华中科技大学光学与电子信息学院院长,2016年3月至2019年1月曾任武汉光电国家研究中心副主任,现任华中科技大学副校长。
在科学研究方面,长期从事光电子器件与集成方面的研究工作,先后主持国家863计划、973计划课题、国家杰出青年基金项目、基金委重大国际合作项目、基金委重点基金项目、基金委重大科学仪器研制项目、国家重点研发计划项目等,发表了国际主流期刊论文350篇以上,发表论文被Web of Science引用超过6000次,Google Scolar统计引用超过8000次,先后主持和参与获得省部级自然科学一等奖4项,授权发明专利16项。代表性学术贡献主要有:
1. 系统研究了半导体光放大器理论建模、器件设计、芯片集成和功能应用,提出半导体光放大器和梳状滤波器结合同时实现多信道光信号处理的方案,研究出半导体光放大器、延时干涉仪、阵列波导光栅等9个功能性器件集成的单片集成芯片,并实现4信道50Gb/s信号的同时光信号处理;提出延时干涉解调和半导体光放大器相结合的方案实现可编程逻辑功能,研究出多个半导体光放大器、延时干涉仪集成的单片集成芯片,成功实现40Gb/s速率下两路信号的所有逻辑最小项产生;基于半导体光放大器实现多种逻辑门功能的工作中,工作原理和实验结果都被国际上流行的《Fiber-Optic Communication Systems》教材直接引用。是国际上发表半导体光放大器相关论文最多的研究者,在国际主流期刊发表相关论文超过150篇,合作出版专著《半导体光放大器及应用》,获省部级自然科学一等奖3项。
2. 系统研究了硅基光子学器件及单片集成系统:针对光纤与芯片的高效耦合,围绕如何增加耦合效率、提高3dB带宽、减小器件尺寸和降低制作工艺,展开了系统的研究工作,通过变周期结构,得到耦合损耗仅为-1.1dB的光栅耦合器;针对Ge/Si波导光探测器,在不影响光学结构的前提下,利用高频螺旋电极在信号极(S)引入片上电感、利用 wire bonding 在地级(G)引入片外金线,寄生参数受限带宽从30 GHz提升至67GHz以上。在突破光纤与集成芯片高效耦合、偏振控制和偏振旋转、混频、高速Ge/Si探测器等核心技术基础上,和华为技术有限公司合作成功实现400Gb/s硅基相干接收芯片。
3. 系统研究了非线性光信号处理和线性光信号处理的工作机制:率先发展了基于频谱变换原理实现线性光信号处理的学术思路,建立了较为完善的理论分析模型,很好地解释了基于滤波器实现线性光信号处理的各种实验结果,并进一步发展了基于频谱变换原理实现常系数微分方程和微分方程组的学术思路,并提出了针对任意维度微分方程组求解的通用方案;系统研究了基于表面等离激元增强非线性效应的工作方案,基于等离子体狭缝波导和石墨烯结合实现带宽大于120GHz的光电探测器,并成功实现偏振复用接收机和针对高级调制格式的相干接收机,实现224Gb/s信号的接收。
在人才培养方面,主持国家精品课程和国家精品资源共享课程《光纤通信技术》。先后培养和合作培养研究生80余人,1人获全国百篇优博论文,2人获全国百篇优博论文提名,6人获湖北省优秀博士学位论文奖,培养的研究生中已有4人获得国家优秀青年基金的资助,有近20名在华为技术有限公司从事光子器件研发工作。担任国家试点学院院长期间,面向每年600多人的本科生学生群体,基于核心课程群,依托优质学科平台和产业资源,探索面向群体的创新人才培养模式改革,作为第一完成人获2018年度国家教学成果一等奖。

联系方式:

Business Address: Room C506, Wuhan National Laboratory for Optoelectronics, Huazhong University of Science and Technology, Wuhan, Hubei, China, 430074
Home Phone: +86-13871262929
Work Phone: +86-27-87793416
Mobile Phone: +86-13871262929
E-mail: xlzhang@mail.hust.edu.cn

教育经历:

1995.9---2010.12 Postgraduate in HUST
1992.7---1995.8 Engineer in Laser Equipment Co. Ltd. of HUST
1988.9---1992.7 Undergraduate in HUST1

工作经历:

June.,2018---Current Vice president of HUST
Feb.,2016---Current Deputy Director of WNLO
Sep.,2012---Current Dean of School of Optical and Electronic Information, HUST
Feb.,2011---Feb.,2016 Director of Division of Optoelectronic Devices and Integration in WNLO, HUST
Nov.,2004---Current Full Professor of HUST
Aug.,2001---Nov.,2004 Associate Professor of HUST
July.,1992---Aug.,1995 Engineer in Laser Equipment Co. Ltd. of HUST

主要研究方向:

Optical Signal Processing Technologies and Devices for Next Generation Optical Network, High Performance Computing, Optical Instrumentation and Microwave Optical Systems1

学术兼职:

获奖情况:

1. The first-class award of natural science in Hubei Province in 2013 Sponsored by National Science Fund for Distinguished Young Scholars of NSFC in 2011
2. The first-class award of natural science in Hubei Province in 2009
3. Awarded as Lecturer of National Distinguished Courses of China in 2009
4. Sponsored by foundation of Outstanding Young Scholars in Hubei Province in 2005
5. Awarded as New Century Talents by Ministry of Education of China in 2004
6. Associate editor of OSA Journal “Photonics Research”; Topical editor of Springer Journal “Frontiers in Optoelectronics”;
7. Chairman of Instrument and Control Society in Hubei Province of China; Life membership of OSA; Senior Membership of IEEE;
8. Co-chair of Technical program committee of Optoelectronics and Communications Conference (OECC’2015), Shanghai, China; Co-chair of OSA Topical Meeting, Optoelectronic Devices & Integration (OEDI’2015); Chair of Section “Optical signal processing” in PIERS’2014, Guangzhou; Co-chair of OSA Topical Meeting, OEDI’2014; Co-chair of OSA Topical Meeting, Information Optoelectronics, Nanofabrication and Testing (IONT’2012); Local organization chair of OEDI SECTION in International Photonics and Optoelectronics Meeting (POEM’2011); Local organization chair of OEDI SECTION in POEM’2010; Co-chair of Workshop on Plasmonics in POEM’2011;
9. Plenary talk in International Conference on Advanced Infocomm Technology (ICAIT’2014), Fuzhou; Invited talk in Photonics Asia’2014, Beijing; Invited talk in International Workshop on Optical Signal Processing and Optical Switching (IWOO’2014), Osaka; Invited talk in Joint Symposium on Opto- and Microelectronic Devices and Circuits (SODC’2014), Germany; Invited talk in Progress In Electromagnetics Research Symposium (PIERS’2014), Guangzhou; Invited talk in Sino-French workshop on Photonics and Optoelectronics, Paris; Invited talk in Asia Communications and Photonics Conference (ACP’2013), Beijing; Invited talk in IWOO’2013, Edinburgh; Invited talk in ACP’2011, Shanghai; Invited talk in ICAIT’2013, Taiwan; Invited talk in IWOO’2012, Japan; Invited talk in SODC’2012, Hangzhou; Invited talk in International Conference on Optical Communications and Networks (ICOCN’2012), Guangzhou; Invited talk in IWOO’2011, Chengdu; Invited talk in ICAIT’2011, Wuhan; Invited talk in IWOO’2010, Tokoyo; Invited talk in ICAIT’2010, Haikou; Invited talks in SODC’2010, Berlin; Invited talks in IWOO’2009, Shanghai; Invited talks in ICAIT’2009, Shenzhen; Invited talk in’2008, Wuhan

代表论文:

1.         W Dong, Z Huang, J Hou, X. L. Zhang, et al. Integrated all-optical programmable logic array based on semiconductor optical amplifiers[J]. Optics Letters, 43, 2150-2153, 2018.

2.         W Dong, J Hou, and X. L. Zhang. Investigation on Expanding the Computing Capacity of Optical Programmable Logic Array Based on Canonical Logic Units [J]. Journal of Lightwave Technology, 36, 3949-3958, 2018.

3.         G. Dong, Y. Wang, X. L. Zhang, et al. High-contrast and low-power all-optical switch using Fano resonance based on a silicon nanobeam cavity. Optics Letters 43, (2018).

4.         G. Dong, W. Deng, X. L. Zhang, et al. Ultra-compact multi-channel all-optical switches with improved switching dynamic characteristics. Optics Express 26, 25630-25644, (2018).

5.         Z Huang, T Cao, X. L. Zhang, et al. Monolithic integrated chip with SOA and tunable DI for multichannel all-optical signal processing [J]. IEEE Photonics Journal, 10, 1-9, 2018.

6.         Y Duan, L Chen, X. L. Zhang, et al. Ultrafast electrical spectrum analyzer based on all-optical fourier transform and temporal magnification. Optics Express, 25, 7520-7529, 2017.

7.         J Hou, J Dong, and X. L. Zhang. On-chip optical feedback systems for solving systems of ordinary differential equations. Journal of Lightwave Technology, 35, 5185-5192, 2017.

8.         L Chen, Y Duan , X. L. Zhang, et al. Frequency-domain light intensity spectrum analyzer based on temporal convolution[J]. Optics Letters, 42, 2726-2729, 2017.

9.         J Hou, J Dong, and X. L. Zhang. Optical solver for a system of ordinary differential equations based on an external feedback assisted microring resonator[J]. Optics Letters, 42, 2310-2313, 2017.

10.     L Chen, Y Duan, H Zhou, X. L. Zhang, et al. Real-time broadband radio frequency spectrum analyzer based on parametric spectro-temporal analyzer (PASTA)[J]. Optics Express, 25, 9416-9425, 2017.

11.     J Zou, Y Yu, and X. L. Zhang. Two-dimensional grating coupler with a low polarization dependent loss of 0.25 dB covering the C-band[J]. Optics Letters, 41, 4206-4209, 2016.

12.     J Hou, J Dong, and X. L. Zhang. Reconfigurable symmetric pulses generation using on-chip cascaded optical differentiators [J]. Optics Express, 24, 20529-20541, 2016.

13.     T Cao, L Chen, Y Yu, and X. L. Zhang. Ultrafast gain recovery in a QW-SOA and its application for 40 Gb/s regenerative format conversion from NRZ-DPSK to RZ-OOK[J]. JOSA B, 33, 1291-1297, 2016.

14.     J Hou, L Chen, W Dong, and X. L. Zhang. 40 Gb/s reconfigurable optical logic gates based on FWM in silicon waveguide [J]. Optics Express, 24, 2701-2711, 2016.

15.     Chen, Kaisheng, Jie Hou, Zhuyang Huang, Tong Cao, Jihua Zhang, Yuan Yu and Xinliang Zhang (2015). "All-optical 1st-and 2nd-order differential equation solvers with large tuning ranges using Fabry-Perot semiconductor optical amplifiers." Optics Express 23(3): 3784-3794.

16.     Wang, Zheqi, Lei Shi, Yi Liu, Xinbiao Xu and Xinliang Zhang (2015). "Optical Nonreciprocity in Asymmetric Optomechanical Couplers." Scientific Reports 5.

17.     Wang, Zheqi, Lei Shi, Xinbiao Xu, Jihua Zhang, Jiali Zhang and Xinliang Zhang (2015). "Optical nonreciprocity with large bandwidth in asymmetric hybrid slot waveguide coupler." Optics Express 23(3): 3690-3698.

18.     Yang, Weili, Yu Yu, Mengyuan Ye, Guanyu Chen, Chi Zhang and Xinliang Zhang (2015). "Phase regeneration for polarization-division multiplexed signals based on vector dual-pump nondegenerate phase sensitive amplification." Optics Express 23(3): 2010-2020.

19.     Cao, Tong, Liao Chen, Yu Yu and Xinliang Zhang (2014). "Experimental demonstration and devices optimization of NRZ-DPSK amplitude regeneration scheme based on SOAs." Optics Express 22(26): 32138-32149.

20.     Chen, Kaisheng, Zhuyang Huang, Gaoneng Dong and Xinliang Zhang (2014). "Design of an ultra-short coupler in an asymmetric twin-waveguide structure using transformation optics." Applied Optics 53(33): 7831-7837.

21.     Liao, Shasha, Yunhong Ding, Christophe Peucheret, Ting Yang, Jianji Dong and Xinliang Zhang (2014). "Integrated programmable photonic filter on the silicon-on-insulator platform." Optics Express 22(26): 31993-31998.

22.     Lei, L., J. J. Dong, B. R. Zou, Z. Wu, W. C. Dong and X. L. Zhang (2014). "Expanded all-optical programmable logic array based on multi-input/output canonical logic units." Optics Express 22(8): 9959-9969.

23.     Liu, Y., L. Shi, X. B. Xu, P. Zhao, Z. Q. Wang, S. L. Pu and X. L. Zhang (2014). "All-optical tuning of a magnetic-fluid-filled optofluidic ring resonator." Lab on a Chip 14(16): 3004-3010.

24.     Min, S. C., S. S. Liao, C. L. Zou, X. L. Zhang and J. J. Dong (2014). "Route-asymmetrical optical transmission and logic gate based on optical gradient force." Optics Express 22(21): 25947-25952.

25.     Wu, Z., J. J. Dong, J. Hou, S. Q. Yan, Y. Yu and X. L. Zhang (2014). "Temporal imaging using a time pinhole." Optics Express 22(7): 8076-8084.

26.     Wu, Z., L. Lei, J. J. Dong and X. L. Zhang (2014). "Triangular-shaped pulse generation based on self-convolution of a rectangular-shaped pulse." Optics Letters 39(8): 2258-2261.

27.     Wu, Z., L. Lei, J. J. Dong, J. Hou and X. L. Zhang (2014). "Reconfigurable Temporal Fourier Transformation and Temporal Imaging." Journal of Lightwave Technology 32(23): 3963-3968.

28.     Xiang, L., D. S. Gao, Y. Yu, M. Y. Ye, B. R. Zou and X. L. Zhang (2014). "Silicon-Based Integrated Comb Filter and Demultiplexer for Simultaneous WDM Signal Processing." IEEE Journal of Selected Topics in Quantum Electronics 20(4).

29.     Xu, Y. M., C. Caer, D. S. Gao, E. Cassan and X. L. Zhang (2014). "High efficiency asymmetric directional coupler for slow light slot photonic crystal waveguides." Optics Express 22(9): 11021-11028.

30.     Yang, T., J. J. Dong, L. J. Lu, L. J. Zhou, A. L. Zheng, X. L. Zhang and J. P. Chen (2014). "All-optical differential equation solver with constant-coefficient tunable based on a single microring resonator." Scientific Reports 4.

31.     Yang, W. L., Y. Yu, M. Y. Ye, J. H. Zou, G. Y. Chen and X. L. Zhang (2014). "Wide Locking Range and Multi-Channel Clock Recovery Using a Silicon Microring Resonator." IEEE Photonics Technology Letters 26(3): 293-296.

32.     Zhang, J. H., E. Cassan and X. L. Zhang (2014). "Electrically controlled second-harmonic generation in silicon-compatible plasmonic slot waveguides: a new modulation scheme." Optics Letters 39(13): 4001-4004.

33.     Zhang, J. H., E. Cassan and X. L. Zhang (2014). "Wideband and Compact TE-Pass/TM-Stop Polarizer Based on a Hybrid Plasmonic Bragg Grating for Silicon Photonics." Journal of Lightwave Technology 32(7).

34.     Zhang, J. H., L. Shi, Y. L. Wang, E. Cassan and X. L. Zhang (2014). "On-chip high-speed optical detection based on an optical rectification scheme in silicon plasmonic platform." Optics Express 22(22): 27504-27514.

35.     Zhao, P., L. Shi, Y. Liu, Z. Q. Wang, S. L. Pu and X. L. Zhang (2014). "Iron-oxide nanoparticles embedded silica microsphere resonator exhibiting broadband all-optical wavelength tunability." Optics Letters 39(13): 3845-3848.

36.     Zheng, A. L., J. J. Dong, L. Lei, T. Yang and X. L. Zhang (2014). "Diversity of photonic differentiators based on flexible demodulation of phase signals." Chinese Physics B 23(3).

37.     Zhou, H. L., J. J. Dong, S. Q. Yan, Y. F. Zhou, L. Shi and X. L. Zhang (2014). "Manipulation of orbital angular momentum beams based on space diffraction compensation." Optics Express 22(15): 17756-17761.

38.     Zhou, H. L., J. J. Dong, L. Shi, D. X. Huang and X. L. Zhang (2014). "Hybrid coding method of multiple orbital angular momentum states based on the inherent orthogonality." Optics Letters 39(4): 731-734.

39.     Zhou, H. L., S. Q. Yan, J. J. Dong and X. L. Zhang (2014). "Double metal subwavelength slit arrays interference to measure the orbital angular momentum and the polarization of light." Optics Letters 39(11): 3173-3176.

40.     Zou, Jinghui, Yu Yu, Mengyuan Ye, Lei Liu, Shupeng Deng, Xiaogeng Xu and Xinliang Zhang (2014). "Short and efficient mode-size converter designed by segmented-stepwise method." Optics Letters 39(21): 6273-6276.

41.     Zou, J. H., Y. Yu, W. L. Yang, Z. Wu, M. Y. Ye, G. Y. Chen, L. Liu, S. P. Deng and X. L. Zhang (2014). "An SOI based polarization insensitive filter for all-optical clock recovery." Optics Express 22(6): 6647-6660.

42.     Yang, T., J. J. Dong, L. Liu, S. S. Liao, S. S. Tan, L. Shi, D. S. Gao and X. L. Zhang (2014). "Experimental observation of optical differentiation and optical Hilbert transformation using a single SOI microdisk chip." Scientific Reports 4: 6.

43.     Ye, M. Y., Y. Yu, J. H. Zou, W. L. Yang and X. L. Zhang (2014). "On-chip multiplexing conversion between wavelength division multiplexing-polarization division multiplexing and wavelength division multiplexing-mode division multiplexing." Optics Letters 39(4): 758-761.