研究副教授 电子与电气工程系
刘奂奂于2014年取得新加坡南洋理工大学博士学位,在光纤激光器、光纤传感器、低维纳米材料光学器件领域,具有多年研究经历和多项研究成果。在Nanophotonics, Applied Physics Letters, Optics Letters,等高水平SCI期刊上发表学术论文超40篇,以第一作者发表论文15篇(影响因子>3的7篇,封面文章2篇,期刊优秀论文1篇),主持国家自然科学基金1项,主要参与国家级科研项目6项,授权国家发明专利9项,参与编写英文专著1本;于2010年获得Photonics Global Conference大会优秀论文,2014年获得“国家优秀自费留学生奖学金”,2016年获得“上海市青年东方学者”人才荣誉,2020年获上海市科技进步二等奖。
个人简介
研究领域
光纤激光器
光纤传感器
低维纳米材料光学器件
学术成果 查看更多
1. H. Liu, Z. Li, Y. Yu, J. Lin, S. Liu, F. Pang, T. Wang, “Nonlinear Optical Properties of Anisotropic 2D Layered Materials for Ultrafast Photonics,” Nanophotonics, 9(7): 1651-1673, 2020.
2. H. Liu, Z. Li, W. Song, Y. Yu, F. Pang, and T. Wang, “MoS2/Graphene heterostructure incorporated passively mode-locked fiber laser: from anomalous to normal average dispersion,” Optical Materials Express, 10(1):46-56, 2020.
3. Z. Guo, H. Liu, L. Xiang, L. Chen, J. Yang, J. Wen, Y. Shang, T. Wang, and F. Pang, “Generation of perfect vortex beams with polymer-based phase plate,” IEEE Photonics Technology Letters, 32(10), 565-568, 2020.
4. Z. Chen, L. Zhang, H. Liu, P. Peng, Z. Liu, S. Shen, N. Chen, S. Zheng, J. Li, and F. Pang, “3D Printing Technique-Improved Phase-Sensitive OTDR for Breakdown Discharge Detection of Gas-Insulated Switchgear,” Sensors, 20(4): 1045, 2020.
5. Z. Wang, J. Chen, H. Wei, H. Liu, Z. Ma, N. Chen, Z. Chen, T. Wang, and F. Pang, “A Sapphire Fabry–Perot Interferometer for High-Temperature Pressure Sensing,” Applied Optics, 59(17):5189-5196, 2020.
6. H. Liu, Y. Yu, W. Song, Q. Jiang, and F. Pang, “Recent development of flat supercontinuum generation in specialty optical fibers,” Opto-Electronic Advances, 2(2):180020, 2019. 【封面文章】
7. H. Liu, F. Pang, L. Hong, Z. Ma, L. Huang, Z. Wang, J. Wen, Z. Chen, and T. Wang, “Crystallization-induced refractive index modulation on sapphire-derived fiber for ultrahigh temperature sensing,” Optics Express, 27(5): 6201-6209, 2019.
8. J. Yang, H. Liu, J. Wen, L. Chen, Y. Shang, N. Chen, S. Huang, T. Wang, and F. Pang, “Cylindrical vector modes based Mach-Zehnder interferometer with vortex fiber for sensing applications”, Applied Physics Letters, 115:051103, 2019.
9. Z. Wang, H. Liu, Z. Ma, Z. Chen, T. Wang, and F. Pang, “High temperature strain sensing with alumina ceramic derived fiber based Fabry-Perot interferometer,” Optics Express, 27(20): 27691-27701, 2019. (IF: 3.488)
10. H. Liu, Y. Yu, W. Song, Q. Jiang, F. Pang, and T. Wang, “Spectrally Flat Supercontinuum Generation in a ZBLAN Fiber Pumped by Erbium-Doped Mode-Locked Fiber Laser,” Photonics Sensors, 9(4):302-308, 2019.
11. F. Pang, H. Zheng, H. Liu, J. Yang, N. Chen, Y. Shang, S. Ramachandran, and T. Wang, “The Orbital Angular Momentum Fiber Modes for Magnetic Field Sensing” IEEE Photonics Technology Letters, 31(11), 893-896, 2019.
12. Z. Ma, Z. Wang, H. Liu, F. Pang, Z. Chen, and T. Wang, “Tensile Strength and Failure Behavior of Bare Single Mode Fibers,” Optical Fiber Technology, 52:101966, 2019.
13. H. Liu, W. Song, Y. Yu, Q. Jiang, F. Pang, and T. Wang, “Black Phosphorus-Film with Drop-Casting Method for High-Energy Pulse Generation from Q-Switched Er-Doped Fiber Laser,” Photonics Sensors, 9(3):239-245, 2019.
14. Y. Shao, H. Liu, P. Peng, F. Pang, G. Yu, Z. Chen, N. Chen, and T. Wang, “Distributed Vibration Sensor With Laser Phase-Noise Immunity by Phase-Extraction φ-OTDR,” Photonics Sensors, 9(3):223-229, 2019.
15. G. Sui, H. Liu, F. Pang, J. Cheng, and T. Wang, “Broadband Acoustic Vibration Sensor Based on Cladding-Mode Resonance of Double-Cladding Fiber,” Photonics Sensors, 9(3):230-238, 2019.
16. 【封面文章,优秀论文】 刘奂奂,蒋巧,宋伟,喻叶,李子龙,庞拂飞,L波段可切换双波长被动锁模光纤激光器,《中国激光》,46(7),0701007, 2019.
17. H. Liu, F. F. Pang, L. Lv, X. Mei. Y. Song, J. Chen, and T. Wang, “True Phase Measurement of Distributed Vibration Sensors Based on Heterodyne φ-OTDR,” IEEE Photonics Journal, 10(1): 7101309, 2018.
18. J. Yang, H. Liu, F. Pang, J. Wen, H. Zheng, L. Chen, X. He, Y. Shang, N. Chen, Y. Li, and T. Wang, “All-Fiber Multiplexing and Transmission of High-Order Circularly Polarized Orbital Angular Momentum Modes with Mode Selective Couplers,” IEEE Photonics Journal, 11(3):7202909, 2018.
19. X. Mei, F. Pang, H. Liu, G. Yu, Y. Shao, T. Qian, C. Mou, L. Lv, and T. Wang, “Fast coarse-fine locating method for φ-OTDR,” Optics Express, 26(3): 2659-2667, 2018.
20. S. Yu, F. Pang, H. Liu, X. Li, J. Yang, and T. Wang, “Compositing orbital angular momentum beams in Bi4Ge3O12 crystal for magnetic field sensing,” Applied Physics Letters, 111(9):091107, 2017.
21. T. Tu, F. Pang, S. Zhu, J. Cheng, H. Liu, J. Wen, and T. Wang, “Excitation of Bloch surface wave on tapered fiber coated with one-dimensional photonic crystal for refractive index sensing,” Optics Express, 25(8):9019, 2017.
22. L. Hong, F. Pang, H. Liu, J. Xu, Z. Chen, Z. Zhao, and T. Wang, “Refractive Index Modulation by Crystallization in Sapphire-Derived Fiber,” IEEE Photonics Technology Letters, 29(9):723, 2017.
23. J. Xu, H. Liu, F. Pang, L. Hong, Z. Ma, Z. Zhao, N. Chen, Z. Chen, and T. Wang, “Cascaded Mach-Zehnder interferometers in crystallized sapphire-derived fiber for temperature-insensitive filters,” Optical Material Express, 7(4):1406-1413, 2017.
24. Y. Zhang, F. Pang, H. Liu, X. Jin, S. Huang, Y. Li, J. Wen, Z. Chen, M. Wang, and T. Wang, “Generation of the first-order OAM modes in ring fibers by exerting pressure technology,” IEEE Photonics Journal, 9(2): 7101609, 2017.
25. F. Pang, M. He, H. Liu (通信作者), X. Mei, J. Tao, T. Zhang, X. Zhang, N. Chen, and T. Wang, “A fading-discrimination method for distributed vibration sensor using coherent detection of φ-OTDR,” IEEE Photonics Technology Letters, pp(99):1-1, 2016.
26. T. Zhang, F. Pang, H. Liu, J. Cheng, L. Lv, X. Zhang, N. Chen, and T. Wang, “A Fiber-Optic Sensor for Acoustic Emission Detection in a High Voltage Cable System,” Sensors, 16(12):2026, 2016.
27. H. Liu and K. K. Chow, “Amplified spontaneous emission pulses for high-power supercontinuum generation,” Journal of Engineering, 1(1), 2016.
28. H. Liu and K. K. Chow, “High fundamental-repetition-rate bound solitons in a carbon-nanotube-based fiber laser,” IEEE Photonics Technology Letters, 27(8):867, 2015.
29. H. Liu and K. K. Chow, “Dark pulse generation in fiber lasers incorporating carbon nanotubes,” Optics Express, 22(24):29708, 2014.
30. H. Liu and K. K. Chow, “Operation-switchable bidirectional pulsed fiber laser incorporating carbon-nanotube-based saturable absorber,” IEEE Journal of Selected Topics in Quantum Electronics, 20(5):0901905, 2014.
31. H. Liu and K. K. Chow, “Enhanced stability of dispersion-managed mode-locked fiber lasers with near-zero net cavity dispersion by high-contrast saturable absorbers,” Optics Letters, 39(1):150, 2014.
32. H. Liu, Y. Yang, and K. K. Chow, “Enhancement of thermal damage threshold of carbon-nanotube-based saturable absorber by evanescent-field interaction on fiber end,” Optics Express, 21(16):18975, 2013.
33. H. Liu and K. K. Chow, “Flat super-continuum generation using carbon nanotube-based mode-locked laser and normal dispersion photonic crystal fibre,” Electronics Letters, 49(16):1020, 2013.
34. H. Liu, K. K. Chow, S. Yamashita, and S. Y. Set, “Carbon-nanotube-based Q-switched fiber laser for high pulse generation,” Optics and Laser Technology, 45:713, 2013.
35. H. Liu, F. Pang, H. Guo, W. Cao, Y. Liu, N. Chen, Z. Chen, and T. Wang, “In series double cladding fibers for simultaneous refractive index and temperature measurement,” Optics Express, 18(12):13072, 2010.