教师名录
孙云旭
通讯地址:深圳西丽深圳大学城哈工大校区
电子邮件:sunyunxu (AT) hitsz.edu.cn
联系电话:86-755-26033001

个人简介

研究方向

非线性光学
量子光学
特殊光纤设计与光纤传感
硅光子学

教育经历

2000-2006  博士,物理学,清华大学
1995-2000  学士,应用物理学,北京工业大学

研究与工作经历

  
  

专业资质与学术兼职

2006  Member of IEEE

科研项目

  

科研成果及奖励

2008  The Japanese society of Microscopy Award for the scientific Paper in 2008

发明专利

申请号:201210008636.1,一种线性腔內光纤布拉格光栅阵列传感系統

论文及著作

List of Publications (last 5 years)
1. Sun, Yunxu, Xuguang Shao, Tianye Huang, Zhifang Wu, Timothy Lee, Shum Ping Perry and Gilberto Brambilla. "Analysis of One-Third Harmonic Generation in Waveguides." Journal of the Optical Society of America B 31, no. 9 (2014): 2142-2149.
2.T. Wu, Y. Sun, X. Shao, P. P. Shum, and T. Huang, "Efficient phase-matched third harmonic generation in an asymmetric plasmonic slot waveguide," Opt. Express 22, 18612-18624 (2014).
3. Yu, X.L., Y. Yao, Y.X. Sun, J.J. Tian and C. Liu, The influence of the sampling dots on the analysis of the wave front aberration by using the covariance matrix method. Optik, 2012. 123(9): p. 792-795.
4. Cong, S., Y.X. Sun, Y.X. Zhao and L.F. Pan, Demodulation of a Fiber Bragg Grating Strain Sensor by a Multi-wavelength Fiber Laser, in Third International Conference on Smart Materials and Nanotechnology in Engineering, J. Leng, et al., Editors. 2012.
5. Yu, X.L., Y. Yao, Y.X. Sun and J.J. Tian, Stability of Zernike coefficients solved by the covariance matrix method in the analysis of the wave front aberration. Optik, 2011. 122(19): p. 1701-1706.
6. Yu, X.L., Y.X. Sun, Y. Yao, J.J. Tian and S. Cong, Quantum-behaved particle swarm optimization for the synthesis of fibre Bragg gratings filter, in Passive Components and Fiber-Based Devices Viii, B.P. Pal, Editor. 2011.
7. Cong, S., Y.X. Sun, L.F. Pan, Y.T. Fang, J.J. Tian, Y.F. Yang, and Y. Yong, Demodulation of a Fiber Bragg Grating Sensor System Based on a Linear Cavity Multi-wavelength Fiber Laser, in Optical Sensors and Biophotonics Iii, J. Popp, et al., Editors. 2011.
8. Zhao, X.H., Y. Yao, Y.X. Sun, X.C. Xu, J.J. Tian and C. Liu, Condition of Keeping Polarization Property Unchanged in the Circle Polarization Shift Keying System. Journal of Optical Communications and Networking, 2010. 2(8): p. 570-575.
9. Yu, X.L., Y. Yao, W.J. Shi, Y.X. Sun and D.Y. Chen, Study on an automatic processing technique of the circle interference fringe for fine interferometry. Optik, 2010. 121(9): p. 826-830.
10. Xiao, J.J., H.H. Zheng, Y.X. Sun and Y. Yao, Bipolar optical forces on dielectric and metallic nanoparticles by evanescent wave. Optics Letters, 2010. 35(7): p. 962-964.
11. Xiao, J.J., H.H. Zheng, Y.X. Sun and Y. Yao, Bipolar optical forces on dielectric and metallic nanoparticles by evanescent wave (vol 35, pg 962, 2010). Optics Letters, 2010. 35(11): p. 1853-1853.
12. Tian, J.J., Y. Yao, Y.X. Sun, X.C. Xu, X.H. Zhao and D.Y. Chen, Flat broadband erbium-doped fiber ASE source based on symmetric nonlinear optical loop mirror. Laser Physics, 2010. 20(8): p. 1760-1766.
13. Liu, C., Y. Yao, Y.X. Sun and X.H. Zhao, Analysis of average capacity for free-space optical links with pointing errors over gamma-gamma turbulence channels. Chinese Optics Letters, 2010. 8(6): p. 537-540.
14. Liu, C., Y. Yao, Y.X. Sun, J.J. Xiao and X.H. Zhao, Average capacity optimization in free-space optical communication system over atmospheric turbulence channels with pointing errors. Optics Letters, 2010. 35(19): p. 3171-3173.
15. Zhao, X.H., Y. Yao, Y.X. Sun and C. Liu, Circle Polarization Shift Keying With Direct Detection for Free-Space Optical Communication. Journal of Optical Communications and Networking, 2009. 1(4): p. 307-312.
16. Zhao, X.H., Y. Yao, Y.X. Sun and C. Liu, Condition for Gaussian Schell-model beam to maintain the state of polarization on the propagation in free space. Optics Express, 2009. 17(20): p. 17888-17894.
17. Tian, J.J., Y. Yao, Y.X. Sun, X.L. Yu and D.Y. Chen, Multiwavelength Erbium-doped fiber laser employing nonlinear polarization rotation in a symmetric nonlinear optical loop mirror. Optics Express, 2009. 17(17): p. 15160-15166.
18. Liu, C., Y.X. Sun, Y. Yao, X.H. Zhao and Ieee, Analysis of Direct Detection and Coherent Detection in Wireless Optical Communication with Polarization Shift Keying. 2009 Lasers & Electro-Optics & the Pacific Rim Conference on Lasers and Electro-Optics, Vols 1 and 2. 2009. 957-958.
19. Tian, J.J., Y. Yao, Y.X. Sun, W.J. Shi, X.H. Zhao and X.L. Yu, Research of the light reflex surface defects detection technology - art. no. 683418, in Optical Design and Testing Iii, Pts 1 and 2, Y. Wang, et al., Editors. 2008. p. 83418-83418.

会议论文及发表演说

Photonics Global conference 2012, Inivited Talk:Intra-cavity Multi-FBG Sensing system Based on Fiber Laser, Singapore

任教和任导师经历

  非线性光学
激光是本世纪科学史上最重大的发明之一,它的出现开创了许多新的研究领域,非线性光学正是激光出现后发展起来的一门崭新的学科,研究光与物质的非线性相互作用以及由此导致的光波之间的非线性相互作用,是现阶段光学研究的前沿领域之一,也是非线性光通信的重要理论基础。非线性光学是一门介于基础与应用之间的学科,随着实验与理论研究的深入,它几乎在所有科学领域中都获得广泛的应用。非线性光学的产生和发展,不仅给光学这门古老的学科增添了新的活力,而且在未来的科技世界中将占有重要的一席之地。
本课程为具有电动力学或经典电磁场理论,并具备一定量子力学知识的研究生设置此课程。除了讨论非线性光学的理论基础外,还主要介绍在非线性介质中产生的各类非线性光学现象与超快光学现象,并且注意介绍与光通信及光电子有关的最新进展,是通信及其光学各专业研究生必须具备的理论基础。
课程分别从经典理论、半经典理论、量子理论讲授光学非线性现象的基本原理。内容涉及非线性光相互作用的经典波动方程,非线性极化率的量子力学理论,二阶非线性光学效应,三阶光学非线性效应,非线性折射率,自发光散射理论,受激拉曼散射,受激布里渊散射,双光子吸收,超快激光脉冲的产生与描述,超短激光脉冲的传播及其非线性效应,非线性与超快激光光谱学。
教材及参考书:
1. The Principles of Nonlinear Optics, Y. R. Shen, Wiley, 1984(非线性光学原理,科学出版社,1997)
2. Nonlinear Optics, Robert W. Boyd, Academic, 2003
3. Handbook of Nonlinear Optics, Richard Sutherland, Marcel, 2003
4. Nonlinear Optics in Telecommunications, Thomas Schneider, Springer, 2004
5. 非线性光学, 石顺祥陈国夫赵卫刘继芳,西安电子科大出版社
最后更新:2019-03-07 17:21:15