王志
性别 : 男 所属部门 : 现代光学研究所
职称 : 教授 学历 : 博士
行政职务 : 所学专业 :
办公电话 :
邮箱 : zhiwang@nankai.edu.cn
研究方向 : 光纤光子学与光通信传感技术



个人简历 1998年7月获天津大学工程力学专业和无线电技术专业工学双学士学位，2001年3月在天津大学机械工程学院获固体力学专业工学硕士学位，2005年7月获南开大学光学专业理学博士学位。从2005年7月至2007年6月在南开大学信息学院进行博士后研究工作，2006年在英国巴斯大学进行学术访问，2007年7月留南开大学光学所任教。目前主要的研究方向包括：光子晶体光纤/多模光纤模式控制理论、微结构光纤传感技术、超快光纤激光技术、非线性光纤光学、多模光纤非线性时空动力学过程。



科研项目/成果/获奖/专利 少模光纤中孤子动力学特性与时空锁模光纤激光器的研究----2018-01-01到2021-12-31
光子带隙光纤制备及多维复用器件理论与关键技术----2017-01-01到2020-12-31
基于光流控光子晶体光纤的模式调控和传感技术研究----2014-04-01到2017-03-31
波长可调谐单片集成高速激光器阵列芯片和模块----2013-01-01到2015-12-31
限制超衍射成像分辨力的物理因素和解决途径----2013-07-01到2017-06-30
基于光子晶体光纤的克尔腔孤子的动力学特性与应用研究----2012-01-01到2015-12-31
基于液晶填充双芯光子带隙光纤的可调光电子器件----2009-01-01到2011-12-31
基于光子带隙光纤的可调谐光电子器件----2009-01-01到2011-12-31
其他纵向项目----1980-01-01到2010-01-01
少模光纤中孤子动力学特性与时空锁模光纤激光器的研究----2018-01-01到2021-12-31
光子带隙光纤制备及多维复用器件理论与关键技术----2017-01-01到2020-12-31
基于光流控光子晶体光纤的模式调控和传感技术研究----2014-04-01到2017-03-31
波长可调谐单片集成高速激光器阵列芯片和模块----2013-01-01到2015-12-31
限制超衍射成像分辨力的物理因素和解决途径----2013-07-01到2017-06-30
基于光子晶体光纤的克尔腔孤子的动力学特性与应用研究----2012-01-01到2015-12-31
基于液晶填充双芯光子带隙光纤的可调光电子器件----2009-01-01到2011-12-31
基于光子带隙光纤的可调谐光电子器件----2009-01-01到2011-12-31
其他纵向项目----1980-01-01到2010-01-01
少模光纤中孤子动力学特性与时空锁模光纤激光器的研究----2018-01-01到2021-12-31
光子带隙光纤制备及多维复用器件理论与关键技术----2017-01-01到2020-12-31
基于光流控光子晶体光纤的模式调控和传感技术研究----2014-04-01到2017-03-31
波长可调谐单片集成高速激光器阵列芯片和模块----2013-01-01到2015-12-31
限制超衍射成像分辨力的物理因素和解决途径----2013-07-01到2017-06-30
基于光子晶体光纤的克尔腔孤子的动力学特性与应用研究----2012-01-01到2015-12-31
基于液晶填充双芯光子带隙光纤的可调光电子器件----2009-01-01到2011-12-31
基于光子带隙光纤的可调谐光电子器件----2009-01-01到2011-12-31
其他纵向项目----1980-01-01到2010-01-01
少模光纤中孤子动力学特性与时空锁模光纤激光器的研究----2018-01-01到2021-12-31
光子带隙光纤制备及多维复用器件理论与关键技术----2017-01-01到2020-12-31
基于光流控光子晶体光纤的模式调控和传感技术研究----2014-04-01到2017-03-31
波长可调谐单片集成高速激光器阵列芯片和模块----2013-01-01到2015-12-31
限制超衍射成像分辨力的物理因素和解决途径----2013-07-01到2017-06-30
基于光子晶体光纤的克尔腔孤子的动力学特性与应用研究----2012-01-01到2015-12-31
基于液晶填充双芯光子带隙光纤的可调光电子器件----2009-01-01到2011-12-31
基于光子带隙光纤的可调谐光电子器件----2009-01-01到2011-12-31
其他纵向项目----1980-01-01到2010-01-01
太瓦光纤飞秒激光器研制----2018-05-01到2022-04-30
宽光谱中红外激射及光谱特性研究----2013-01-01
光子晶体光纤结构设计----2012-02-20
其他横向项目----1980-01-01
宽光谱中红外激射及光谱特性研究----2013-01-01
光子晶体光纤结构设计----2012-02-20
其他横向项目----1980-01-01
论文/专著/教材代表论文

1. Liang, H., Wang, Z., Liu, Y., Li, H., & Zhang, H.. Coupling Characteristics of Selective-Infiltration-Based Locally Tapered Photonic Crystal Fiber. IEEE Photonics Journal, 9(5), **, 2017.
2. Luo, M., Liu, Y., Wang, Z., Li, Z., Zhou, W. Y., Guo, J., ... & Liu, X., Manipulative Dual-Microsphere Lasing Based on Nanosilica Waveguide Integrated in a Simplified Hollow-Core Microstructured Optical Fiber. Journal of Lightwave Technology, 35(11), 2183-2189, 2017.
3. Liu, X., Liu, Y., & Wang, Z.. Double telecom band thermo-optic switch based on dual-line filled photonic liquid crystal fibres. Liquid Crystals, 44(3), 479-483, 2017.
4. Li, H., Wang, Z., Liu, Y., Liang, H., & Han, S., Coupling characteristics of twin-core few-mode all-solid photonic bandgap fiber and their application in mode separation. JOSA B, 34(9), 1811-1816, 2017.
5. Wang, Z., Wang, Z., Liu, Y. G., He, R., Wang, G., Yang, G., & Han, S. . Generation and time jitter of the loose soliton bunch in a passively mode-locked fiber laser. Chinese Optics Letters, 15(8), 080605., 2017.
6. Han, Y., Liu, Y. G., Wang, Z., Huang, W., Chen, L., Zhang, H. W., & Yang, K., Controllable all-fiber generation/conversion of circularly polarized orbital angular momentum beams using long period fiber gratings. Nanophotonics, 2017.
7. Wang, Z., Wang, Z., Liu, Y. G., Zhao, W., Zhang, H., Wang, S.,Yang G., and He R., ”Q-switched-like soliton bunches and noise-like pulses generation in a partially mode-locked fiber laser”, Optics Express, 2016, 24(13):14709-14716.
8. Liu, X., Gong, T., Liu, Y., & Wang, Z.. A novel refractometric sensor based on optofluidic integration of composite core photonic crystal fibers. Journal of Optics, 19(1), 015301, 2016.
9. Han, Y., Liu, Y. G., Huang, W., Wang, Z., Guo, J. Q., & Luo, M. M., Generation of linearly polarized orbital angular momentum modes in a side-hole ring fiber with tunable topology numbers. Optics express, 24(15), 17272-17284, 2016.
10. Guo, J., Liu, Y. G., Wang, Z., Luo, M., Huang, W., Han, T., & Liu, X., Broadband optically controlled switching effect in a microfluid-filled photonic bandgap fiber. Journal of Optics, 18(5), 055706, 2016.
11. Wei Huang、Yange Liu、Zhi Wang、Wanchen Zhang、Mingming Luo、Xiaoqi Liu、Junqi Guo、Bo Liu、Lie Lin ，Generation and excitation of different orbitalangular momentum states in a tunable microstructure optical fiber，Optics Express, 2015, 23(26), p 33741.
12. Mingming Luo、Yange Liu、Zhi Wang、Tingting Han、Junqi Guo、Wei Huang ，Microfluidic assistant beat-frequency interferometer based on a single-hole-infiltrated dual-mode microstructured optical fiber，2014, Optics Express, 22(21), pp 25224-25232.
13. Han, Tingting、Liu, Yan-ge、Wang, Zhi、Guo, Junqi、Wu, Zhifang、Luo, Mingming、Li, Shuo、Wang, Jing、Wang, Wei ，Control and design of fiber birefringence characteristics based on selective-filled hybrid photonic crystal fibers，Optics Express, 22(12), 2014, pp 15002-15016.
14. Junqi Guo、Yange Liu、Zhi Wang、Tingting Han、Wei Huang、Mingming Luo ，Tunable fiber polarizing filter based on a single-hole-infiltrated polarization maintaining photonic crystal fiber，Optics Express, 2014, 22(7), pp 7607-7616.
15. Wei Huang、Yange Liu、Zhi Wang、Bo Liu、Jing Wang、Mingming Luo、Junqi Guo、Lie Lin，Multi-component-intermodal-interference mechanism and characteristics of a long period grating assistant fluid-filled photonic crystal fiber interferometer，Optics Express, 22(5), 2014, pp 5883-5894.
16. Luo M, Liu Y, Wang Z, Han T., Wu Z., Guo J., and Huang W., “Twin-resonance-coupling and high sensitivity sensing characteristics of a selectively fluid-filled microstructured optical fiber”, Optics Express, 2013, 21(25):30911-30917.
17. Zhifang Wu, Yan-Ge Liu, Zhi Wang, Meng Jiang, Wenbin Ji, Tingting Han, Shuo Li, Xuguang Shao, Xuan Quyen Dinh, Swee Chuan Tjin, and Perry Ping Shum, Simultaneous measurement of curvature and strain based on fiber Bragg grating in two-dimensional waveguide array fiber. Optics Letters, 2013, 38(20):4070-4073.
18. Tingting Han, Yan-ge Liu, Zhi Wang, Junqi Guo, Zhifang Wu, Shuanxia Wang, Zhili Li, and Wenyuan Zhou, Unique characteristics of a selective-filling photonic crystal fiber Sagnac interferometer and its application as high sensitivity sensor. Optics Express, 2013, 21(1): 122-128.
19. S. Li, Z. Wang, Y. Liu, T. Han, Z. Wu, C. Wei, H. Wei, J. Li, and W. Tong "Bending sensor based on intermodal interference properties of two-dimensional waveguide array fiber," Optics Letters, 2012, 37: 1610-1612.
20. T. Han, Y. Liu Z. Wang, Z. Wu, S. Wang, and S. Li, "Simultaneous temperature and force measurement using Fabry-Perot interferometer and bandgap effect of a fluid-filled photonic crystal fiber," Optics Express, 2012, 20: 13320-13325.
21. Z. Wu, Y. Liu, Z. Wang, T. Han, S. Li, M. Jiang, P. Shum, and X.Q. Dinh, "In-line Mach-Zehnder interferometer composed of microtaper and long-period grating in all-solid photonic bandgap fiber".," Applied Physics Letters, 2012, vol. 101, 141106.
22. X. Zheng, Y. Liu, Z. Wang, T. Han, C. Wei, and J. Chen, "Transmission and temperature sensing characteristics of a selectively liquid-filled photonic-bandgap-fiber-based Sagnac interferometer," Applied Physics Letters, 2012, vol. 100, 141104.
23. Z. Wu, Z. Wang, Y. Liu, et al., "Mechanism and characteristics of long period fiber gratings in simplified hollow-core photonic crystal fibers," Optics Express, vol. 19, pp. 17344-17349, 2011.
24. Z. Sun, Y. Liu, Z. Wang, B. Tai, T. et al., "Long period grating assistant photonic crystal fiber modal interferometer," Optics Express, vol. 19, pp. 12913-12918, 2011.
25. X. Zheng, Y. Liu, Z. Wang, et al., "Tunable Single-Polarization Single-Mode Photonic Crystal Fiber Based on Liquid Infiltrating," IEEE Photonics Technology Letters, vol. 23, pp. 709-711, 2011.
26. B. Y. Tai, Z. Wang, Y. G. Liu, et al., "High order resonances between core mode and cladding supermodes in long period fiber gratings inscribed in photonic bandgap fibers," Optics Express, vol. 18, pp. 15361-15370, 2010.
27. J. B. Xu, Y. G. Liu, Z. Wang, et al., "Simultaneous force and temperature measurement using long-period grating written on the joint of a microstructured optical fiber and a single mode fiber," Applied Optics, vol. 49, pp. 492-496, 2010.
28. T. T. Han, Y. G. Liu, Z. Wang, et al., "Avoided-crossing-based ultrasensitive photonic crystal fiber refractive index sensor," Optics Letters, vol. 35, pp. 2061-2063, 2010.
29. Q. Shi, Z. Wang, L. Jin, et al., "A hollow-core photonic crystal fiber cavity based multiplexed Fabry-Perot interferometric strain sensor system," IEEE Photonics Technology Letters, vol. 20, pp. 1329-1331, 2008.
30. L. Jin, Z. Wang, Y. G. Liu, et al., "Ultraviolet-inscribed long period gratings in all-solid photonic bandgap fibers," Optics Express, vol. 16, pp. 21119-21131, 2008.
31. Q. Shi, F. Y. Lv, Z. Wang, et al., "Environmentally stable Fabry-Perot-type strain sensor based on hollow-core photonic bandgap fiber," IEEE Photonics Technology Letters, vol. 20, pp. 237-239, 2008.
32. J. B. Du, Y. G. Liu, Z. Wang, et al., "Electrically tunable Sagnac filter based on a photonic bandgap fiber with liquid crystal infused," Optics Letters, vol. 33, pp. 2215-2217, 2008.
33. J. B. Du, Y. G. Liu, Z. Wang, et al., "Liquid crystal photonic bandgap fiber: different bandgap transmissions at different temperature ranges," Applied Optics, vol. 47, pp. 5321-5324, 2008.
34. J. B. Du, Y. G. Liu, Z. Wang, et al., "Thermally tunable dual-core photonic bandgap fiber based on the infusion of a temperature-responsive liquid," Optics Express, vol. 16, pp. 4263-4269, 2008.
35. J. B. Du, Y. G. Liu, Z. Wang, et al., "Characteristics of photonic bandgap fibres with hollow core's inner surface coated by a layer material," Chinese Physics Letters, vol. 25, pp. 164-167, 2008.
36. Y. Yue, G. Kai, Z. Wang, et al., "Highly birefringent elliptical-hole photonic crystal fiber with squeezed hexagonal lattice," Optics Letters, vol. 32, pp. 469-471, 2007.
37. Z. Wang, T. Taru, T. A. Birks, J. C. Knight, et al., " Coupling in dual-core photonic bandgap fibers: theory and experiment ", Opt. Express, 15, pp.4795-4803, 2007.
38. Z. Wang, Y. G. Liu, G. Y. Kai, et al., "Directional couplers operated by resonant coupling in all-solid photonic bandgap fibers," Optics Express, vol. 15, pp. 8925-8930, 2007.
39. L. Jin, Z. Wang, Q. Fang, et al., "Spectral characteristics and bend response of Bragg gratings inscribed in all-solid bandgap fibers," Optics Express, vol. 15, pp. 15555-15565, 2007.
40. L. Jin, Z. Wang, Q. Fang, et al., "Bragg grating resonances in all-solid bandgap fibers," Optics Letters, vol. 32, pp. 2717-2719, 2007.
41. Q. Fang, Z. Wang, G. Y. Kai, et al., "Proposal for all-solid photonic bandgap fiber with improved dispersion characteristics," IEEE Photonics Technology Letters, vol. 19, pp. 1239-1241, 2007.
42. Q. Fang, Z. Wang, L. Jin, et al., "Dispersion design of all-solid photonic bandgap fiber," Journal of the Optical Society of America B-Optical Physics, vol. 24, pp. 2899-2905, 2007.
43. C. S. Zhang, G. Y. Kai, Z. Wang, T. T. Sun, C. Wang, Y. G. Liu, J. F. Liu, W. G. Zhang, S. Z. Yuan, and X. Y. Dong, et al., "Design of tunable bandgap guidance in high-index filled microstructure fibers," Journal of the Optical Society of America B-Optical Physics, vol. 23, pp. 782-786, 2006.
44. Y. Yue, G. Y. Kai, Z. Wang, et al., "Broadband single-polarization single-mode photonic crystal fiber coupler," IEEE Photonics Technology Letters, vol. 18, pp. 2032-2034, 2006.
45. Y. Yue, G. Y. Kai, Z. Wang, et al., "Highly birefringent elliptical-hole photonic crystal fiber with two big circular air holes adjacent to the core," IEEE Photonics Technology Letters, vol. 18, pp. 2638-2640, 2006.
46. Y. Yue, G. Y. Kai, Z. Wang, et al., "Phase and group modal birefringence of an index-guiding photonic crystal fibre with helical air holes," Optics Communications, vol. 268, pp. 46-50, 2006.
47. J. G. Liu, L. Xue, Z. Wang, et al., "Large anomalous dispersion at short wavelength and modal properties of a photonic crystal fiber with large air holes," IEEE Journal of Quantum Electronics, vol. 42, pp. 961-968, 2006.
48. C. S. Zhang, G. Y. Kai, Z. Wang, et al., "Tunable highly birefringent photonic bandgap fibers," Optics Letters, vol. 30, pp. 2703-2705, 2005.
49. Z. Wang, G. Y. Kai, Y. G. Liu, et al., "Coupling and decoupling of dual-core photonic bandgap fibers," Optics Letters, vol. 30, pp. 2542-2544, 2005.
50. C. S. Zhang, G. Y. Kai, Z. Wang, et al., "Transformation of a transmission mechanism by filling the holes of normal silica-guiding microstructure fibers with nematic liquid crystal," Optics Letters, vol. 30, pp. 2372-2374, 2005.
讲授课程 研究生课程《光电子学》，《光学数值计算方法》；本科生课程《光纤通信》



社会兼职中国光学学会高级会员
Optics Letters、Optics Express、Journal of Lightwave Technology、物理学报、中国激光、光学学报等期刊审稿人。