个人资料
教育经历2005.9-2008.6 南开大学 光学 博士1998.9-2001.6 武汉理工大学 材料学 硕士(保送)1994.9-1998.6 武汉理工大学 材料工程 本科
工作经历2018.1-至今 南开大学物理科学学院 教授2016.12-2017.12 韩国IBS软物质与活性物质研究中心 访问学者2011.1-2017.12 南开大学物理科学学院 副教授2008.7-2010.12 南开大学物理科学学院 讲师2001.7-2005.8 长飞光纤光缆有限公司(世界前三) 工艺/研发工程师。在长飞光纤光缆有限公司(位于武汉?中国光谷)工作期间,主要从事新型光纤的设计、研发及工艺控制,先后两次被派往荷兰Draka光纤通信公司(外资方)进行技术培训和交流,参加了多项科技攻关项目,2004 年作为主要研究人员获“武汉市科技进步”二等奖一项,并获光纤发明专利二项。
个人简介涂成厚,男,1976年8月出生,河南信阳人,中共党员,教授、博士生导师,光科学与技术系副主任。2008 年毕业于南开大学物理学院光学专业,获理学博士学位并留校任教。主要从事光场空域调控及应用、飞秒激光微纳加工和非线性光学等方面的研究。先后主持或完成国家自然科学基金面上项目、天津市自然科学基金重点项目和一般项目及校内教改项目等多项课题,作为骨干人员参与国家重大科学研究计划课题三项、国家自然科学基金重点项目一项。在Optica、Science Advances、Photonics Research国内外著名学术刊物发表论文90多篇,多次受邀做会议/学术报告,授权发明专利7项。担任Opt. Lett.、Opt. Express、Sci. Rep.、Appl.Opt.和Science等期刊的审稿人,国家自然科学基金委员会、教育部学位中心评审专家,中国物理学会永久会员。在教学科研过程中,始终注重理论与实际应用的联系,着力培养学生发现问题、分析问题和解决问题的综合素质和能力;注重学生人格品性的培养,因材施教,使每个学生都能开心地学习、工作和生活。
研究方向研究生招生专业:光学 研究方向(光场调控、矢量光场及非线性光学及应用等): · 新型光场的多维度(包括偏振、相位、模式等)调控及应用 · 光场的角动量调控及应用 · 奇点光场及光场拓扑特性 · 光场调控及光学微操控 · 空间结构光场与物质/微结构的非线性相互作用及应用 · 飞秒矢量光场及高效微纳加工 欢迎对光场调控及其应用感兴趣的同学加入课题组,一起探索光场的奥秘! 研究成果科研项目近年来主持项目情况 1. 高等学校博士点基金青年项目:高重复频率飞秒激光刻写铌酸锂光波导器件的机理与实验研究,2010.1-2012.12,主持,已结题 2. 中央高校基本科研业务费专项资金:新型红外增强吸收特性“黑硅”材料的制备、机理及其在红外光探测器中应用研究,2010.6-2012.5,主持,已结题 3. 瞬态光学与光子技术国家重点实验室开放基金:基于飞秒矢量光场的超衍射极限微纳加工研究,2012.12-2014.12,主持,已结题 4. 天津市自然科学基金一般项目:飞秒矢量光场焦场调控及其超衍射极限微纳加工应用研究,2012.4-2015.3,主持,已结题 5. 国家自然科学基金面上项目:飞秒矢量光场的超衍射极限微结构制备及特性研究,2013.1-2016.12,主持,已结题 6. 天津市自然科学基金重点项目:基于“定制”微纳结构的光场调控研究,2016.4-2019.3,主持,已结题 7. 国家自然科学基金面上项目:基于飞秒直写介电微纳结构的光场调控及应用研究,2018.1-2021.12,主持,已结题 8. 国家自然科学基金面上项目:复杂结构偏振奇点光场的生成调控、探测及与物质相互作用研究,2021.1-2024.12,主持,在研 9. 国家自然科学基金面上项目:三维拓扑结构光场定制调控及与物质相互作用研究,2024.1-2027.12,主持,在研 近年来主要参与项目情况 1. 国家重大科学研究计划项目:光场调控及与微结构相互作用研究,第一课题:空间结构光场的调控机理、生成技术和新颖性质,2012.1-2016.12,参与,已结题 2. 国家自然科学基金重点项目:空域分形光场的调控、新效应及其潜在应用,2016.1-2020.12,参与,已结题 3. 国家重点研发计划项目课题:具有拓扑特性的空间光场产生、调控及与微结构相互作用,2017.7-2022.6,参与,已结题 4. 国家重点研发计划项目课题:非相干拓扑结构光场调控及应用,2023.1-2027.12,参与,在研
主持教改项目 南开大学教改项目:《大学物理学基础》考试方式、方法的改革与实践,2014.10-2016.10,主持,已结题
95. Q. Wang, Z.-C. Xia, J.-H. Zhao, X. Zhang, C. H. Tu*, Y. N. Li, and H.-T. Wang*, “Tailoring nonuniform local orbital angular momentum density”, Opt. Lett. 49, 746-749(2024). (Editor's Pick) 94. H. He, Z. X. Chen, H. N. Li*, C.-H. Tu, J. J. Xu*, and A. Alù*, “Evanescent wave spectral singularities in non-Hermitian photonics”, Phys. Rev. B 109, L041405 (2024). 93. Q.Wang, C. H. Tu*, J.-H. Zhao, X. Zhang, Z. Q. Wu, M.-Y. Wang, Y. N. Li, and H.-T. Wang*, “Customization and Information Encoding of Longitudinally Polarized Light Fields”, Adv. Photon. Res. 2300236 (2023). (Inside Cover article) 92. M. Wang, L. Y. Chen, D.-Y. Choi, S. Y. Huang, Q. Wang, C. H. Tu, H. Cheng, J. G. Tian, Y. N. Li*, S. Q. Chen*, and H.-T. Wang*, “Characterization of Orbital Angular Momentum Quantum States Empowered by Metasurfaces,” Nano Lett. 23, 3921-3928 (2023). 91. F. Dai, Q. Q. Tian, S.-Y. Huang, M. Wang, C. H. Tu, Y. N. Li*, Y. Sheng*, H.-T. Wang, “Photon pair generation in lithium niobate waveguide periodically poled by femtosecond laser,” Chin. Opt. Lett. 21, 042701 (2023). 90. Y. Li, S.-Y. Huang, M. Wang, C. H. Tu, X.-L. Wang, Y. N. Li*, and H.-T. Wang*, “Two-Measurement Tomography of High-Dimensional Orbital Angular Momentum Entanglement,” Phys. Rev. Lett. 130, 050805 (2023). 89. K. Wang, J. Li, F. Dai, M. S. Wang, C. H. Wang, Q. Wang, C. H. Tu, Y. N. Li* and H.-T. Wang*, “Robust Pulse-Pumped Quadratic Soliton Assisted by Third-Order Nonlinearity,” Photonics 10, 155 (2023). 88. K. Wang, J. Li, F. Dai, M. S. Wang, C. H. Wang, Q. Wang, C. H. Tu, Y. N. Li* and H.-T. Wang*, “Quadratic microcomb assisted by Kerr nonlinearity”, Front. Phys. 10, 1026618 (2022). 87. F. Dai, S.-Y. Huang, M. Wang, C. H. Tu, Y. N. Li* and H.-T. Wang*, “High-dimensional orbital angular momentum entanglement from an ultrathin nonlinear film”, Front. Phys. 10, 971360 (2022). 86. J.-H. Zhao, Y. Pan*. X.-Z. Gao, R. D. Ma, Z.-X. Man, Z.-C. Ren, C. H. Tu, Y. N. Li and H.-T. Wang*, “Five-dimensional Poincaré sphere system for representing azimuthally varying vector optical fields”, Phys. Rev. A 106, 023506 (2022). 85. Q. Wang, C. H. Tu*, H. He, Z. C. Xia, X. Z. Hou, Y. N. Li, and H.-T. Wang*, “Local angular momentum induced dual orbital effect”, APL Photonics 7, 086102 (2022). (Featured and Cover-1 article) 84. M. Q. Cai, Q. Wang, Y. N. Li, and C. H. Tu*, “Propagation and focusing properties of vortex beams based on light ray tracing”, Front. Phys. 10, 931131 (2022). 83. W. R. Qi, J. Zhou, L. J. Kong, Z. P. Xu, H. X. Meng, R. Liu, Z. X. Wang, C. H. Tu, Y. N. Li*, A. Cabello, J. L. Chen*, and H.-T. Wang*, “ Stronger Hardy-Like Proof of Quantum Contextuality”, Photon. Res. 10, 1582-1593 (2022). 82. M. Q. Cai, Q. Wang, C. H. Tu*, Y. N. Li, and H. T. Wang, “Dynamically taming focal fields of femtosecond lasers for fabricating microstructures,” Chin. Opt. Lett. 20, 010502 (2022). 81. S. Y. Huang, G.-L. Zhang, Q. Wang, M. Wang, C. H. Tu, Y. N. Li*, and H.-T. Wang*, “Spin-to-orbital angular momentum conversion via light intensity gradient,” Optica 9, 1231-1236 (2021). 80. Q. Wang, C. H. Tu*, Y. N. Li, and H. T. Wang*, “Polarization singularities: Progress, fundamental physics, and prospects,” APL Photonics 6, 040901 (2021) (Invited review). 79. W. R. Qi, R. Liu, L. J. Kong, Z. X. Wang, S. Y. Huang, C. H. Tu, Y. N. Li*, and H. T. Wang*, “Pancharatnam–Berry geometric phase memory based on spontaneous parametric down-conversion,” Opt. Lett. 45(3), 682-685 (2020). 78. L. J. Kong, R. Liu, W. R. Qi, Z. X. Wang, S. Y. Huang, C. H. Tu, Y. N. Li*, and H. T. Wang*, “Asymptotical Locking Tomography of High-Dimensional Entanglement,” Chin. Phys. Lett. 37(3), 034204 (2020). 77. J. Q. Lü, X. L. Wang, G. L. Zhang, C. H. Tu, Y. N. Li, and H. T. Wang*, “Bessel-like beams with controllable rotating local linear polarization during propagation,” Opt. Lett. 45(7), 1738-1741 (2020). 76. Y. Pan*, Z. C. Ren, L. J. Kong, C. H. Tu, Y. N. Li, and H. T. Wang*, “Theoretical analysis based on mirror symmetry for tightly focused vector optical fields,” Opt. Express 28(16), 23416-23432 (2020). 75. X. Z. Gao, P. C. Zhao, X. F. Sun, F. Yang, Y. Pan*, Y. N. Li, C. H. Tu, and H. T. Wang*, “Highly purified transversely polarized optical needle generated by the hybridly polarized vector optical field with hyperbolic symmetry,” J. Opt. 22(10), 105604 (2020). 74. W. R. Qi, R. Liu, L. J. Kong, Z. X. Wang, S. Y. Huang, C. H. Tu, Y. N. Li*, and H. T. Wang*, “Double-slit interference of single twisted photons,” Chin. Opt. Lett. 18(10), 102601 (2020). 73. R. Liu, L. J. Kong, Y. Si, Z. X. Wang, W. R. Qi, C. H. Tu, Y. N. Li*, and H. T. Wang*, “Multi-Path Ghost Imaging by Means of an Additional Time Correlation,” Chin. Phys. Lett. 36(4), 044205 (2019). 72. G. L. Zhang, M. Q. Cai, X. L. He, X. Z. Gao, M. D. Zhao, D. Wang, Y. N. Li, C. H. Tu*, and H. T. Wang*, “Pseudo-topological property of Julia fractal vector optical fields,” Opt. Express 27(9), 13263–13279 (2019). 71. R. Liu, L. J. Kong, W. R. Qi, S. Y. Huang, Z. X. Wang, C. H. Tu, Y. N. Li*, and H. T. Wang*, “Compact, robust, and high-efficiency generator of vector optical fields,” Opt. Lett. 44(9), 2382-2385 (2019). 70. L. J. Kong, R. Liu, W. R. Qi, Z. X. Wang, S. Y. Huang, Q. Wang, C. H. Tu, Y. N. Li*, and H. T. Wang*, “Manipulation of eight-dimensional Bell-like states,” Sci. Adv. 5(6), eaat9206 (2019). 69. G. L. Zhang, C. H. Tu, Y. N. Li*, and H. T. Wang*, “Observation of polarization topological singular lines,” Photon. Res. 7(6), 705–710 (2019). 68. M. D. Zhao, X. Z. Gao, Q. Wang, G. L. Zhang, K. Wang, F. Dai, D. Wang, Y. N. Li, C. H. Tu*, and H. T. Wang*, “Multifractal vector optical fields,” Opt. Express 27(15), 20608–20620 (2019). 67. L. J. Kong, Y. N. Li*, R. Liu, W. R. Qi, Q. Wang, Z. X. Wang, S. Y. Huang, Y. Si, C. H. Tu, W. Hu, F. Xu, Y. Q. Lu, and H. T. Wang*, “Complete measurement and multiplexing of orbital angular momentum Bell states,” Phys. Rev. A 100(2), 023822 (2019). 66. Y. Pan*, X. Z. Gao, G. L. Zhang, Y. Li, C. H. Tu, and H. T. Wang*, “Spin angular momentum density and transverse energy flow of tightly focused kaleidoscope-structured vector optical fields,” APL Photonics 4(9), 096102 (2019). 65. Y. Pan*, M. S. Wang, X. Z. Gao, X. Zhang, R. Ma, Y. N. Li, C. H. Tu, and H. T. Wang*, “Energy transfer of the tightly focused hybridly polarized vector optical fields with elliptic symmetry in free space,” J. Opt. Soc. Am. A 36(11), 1898-1907 (2019). 64. Y. Pan*, X. Z. Gao, X. Zhang, J. H. Zhao, P. C. Zhao, Y. N. Li, C. H. Tu, and H. T. Wang*, “Diffraction properties and applications of spatially structured optical fields with fractal amplitude masks,” Appl. Opt. 58(31), 8631-8637 (2019). 63. Z. X. Wang, Y. C. Xie, H. Zhou,S. Y. Huang, M. Wang, R. Liu, W. R. Qi, Q. Q. Tian, L. J. Kong, C. H. Tu, Y. N. Li, and H. T. Wang*, “Identifying the symmetry of an object based on orbital angular momentum through a few-mode fiber,” Chin. Phys. Lett. 36(12), 124207 (2019). 62. Z. X. Wang, Y. C. Xie, S. Y. Huang, H. Zhou, R. Liu, Z. F. Liu, M. Wang, W. R. Qi, Q. Q. Tian, L. J. Kong, C. H. Tu, Y. N. Li, and H. T. Wang*, “Propagation characteristics of orbital angular momentum modes at 810 nm in step-index few-mode fibers”, Chin. Opt. Lett. 17(12), 120601(2019). 61. P. P. Li, M. Q. Cai, J. Q. Lu, D. Wang, G. G. Liu, C. H. Tu, Y. N. Li*, and H. T. Wang*, “Unveiling of control on the polarization of supercontinuum spectra based on ultrafast birefringence induced by filamentation,” J. Opt. Soc. Am. B 35(11), 2916-2922(2018). 60. R. Liu, L. J. Kong, Z. X. Wang, Y. Si, W. R. Qi, S. Y. Huang. C. H. Tu, Y. N. Li*, and H. T. Wang*, “Two-Photon interference constructed by two Hong-Ou-Mandel effects in one Mach-Zehnder interferometer,” Chin. Phys. Lett. 35(9), 090303 (2018). 59. G. G. Liu, K. Wang. Y. H. Lee, D. Wang, P. P. Li, F. W. Gou, Y. N. Li, C. H. Tu*, S. T. Wu, and H. T. Wang*, “Measurement of the topological charge and index of vortex vector optical fields with a space-variant half-wave plate,” Opt. Lett. 43(4), 823-826 (2018). 58. G. L. Zhang, X. Z. Gao, Y. Pan, M. D. Zhao, D. Wang, H. H. Zhang, Y. N. Li, C. H. Tu*, and H. T. Wang*, “Inverse method to engineer uniform-intensity focal fields with arbitrary shape,” Opt. Express 26(13), 16782-16796 (2018). 57. M. D. Zhao, X. Z. Gao, Y. Pan, G. L. Zhang, C. H. Tu, Y. N. Li*, and H. T. Wang*, “Image encryption based on fractal-structured phase mask in fractional Fourier transform domain,” J. Opt. 20, 045703 (2018). 56. X. Z. Gao, Y. Pan, M. D. Zhao, G. L. Zhang, Y. Zhang, C. H. Tu, Y. N. Li*, and H. T. Wang*, “Focusing behavior of the fractal vector optical fields designed by fractal lattice growth model,” Opt. Express 26(2), 1597-1614 (2018). 55. D. Wang, G. G. Liu, J. Q. LÜ, P. P. Li, M. Q. Cai, G. L. Zhang, Y. N. Li, C. H. Tu*, and H. T. Wang*, “Femtosecond polarization-structured optical field meets an anisotropic nonlinear medium,” Opt. Express 26(21), 27726-27747 (2018). 54. D. Wang, Y. Pan, J. Q. Lu, P. P. Li, G. G. Liu, M. Q. Cai, Y. N. Li, C. H. Tu*, and H. T. Wang*, “Controlling optical field collapse by elliptical symmetry hybrid polarization structure,” J. Opt. Soc. Am. B 35(10), 2373-2381(2018). (Spot highlighted) 53. J. Q. Lu, P. P. Li, D. Wang, C. H. Tu, Y. N. Li*, and H. T. Wang*, “Control on helical filaments by twisted beams in a nonlinear CS2 medium,” Opt. Express. 26(22), 29527-29538(2018). 52. J. Q. Lu, P. P. Li, D. Wang, C. H. Tu, Y. N. Li*, and H. T. Wang*, “Extending optical filaments with phase-nested laser beams,” Photon. Res. 6(12), 1130-1136 (2018). 51. Y. N. Li, Z. C. Ren, L. J. Kong, C. H. Tu, and H. T. Wang*, “Trajectory-based unveiling of the angular momentum of photons,” Phys. Rev. A 95(4), 043830 (2017). 50. L. J. Kong, R. Liu, Y. Si, Z. X. Wang, C. H. Tu, Y. N. Li*, and H. T. Wang, “Time-resolved multiple imaging by detecting photons with changeable wavelengths,” Chin. Opt. Lett. 15(8), 081101(2017). 49. Y. Si, L. J. Kong, Y. Zhang, Z. C. Ren, Y. Pan, C. H. Tu, Y. N. Li*, and H. T. Wang*, “Spatial-Variant Geometric Phase of Hybrid-Polarized Vector Optical Fields,” Chin. Phys. Lett. 34(4), 044204 (2017). 96. L. J. Kong, Y. Si, R. Liu, Z. X. Wang, W. R. Qi, C. H. Tu, Y. N. Li*, and H. T. Wang*, “Robust ghost imaging based on degenerate spontaneous parametric down-conversion,” Chin. Phys. Lett. 34(5), 054206 (2017). 47. M. Q. Cai, Z. X. Wang, J. Liang, Y. K. Wang, X. Z. Gao, Y. N. Li, C. H. Tu*, and H. T. Wang*, “High-efficiency and flexible generation of vector vortex optical fields by a reflective phase-only spatial light modulator,” Appl. Opt. 56(22), 6175-6180 (2017). 46. X. Z. Gao, Y. Pan, G. L. Zhang, M. D. Zhao, Z. C. Ren, C. H. Tu, Y. N. Li*, and H. T. Wang*, “Redistributing the energy flow of tightly focused ellipticity-variant vector optical fields,” Photon. Res. 5(6), 640-648 (2017). 45. G. G. Liu, Y. H. Lee, Y. G. Huang, Z. Y. Zhu, G. J. Tan, M. Q. Cai, P. P. Li, D. Wang, Y. N. Li, S. Pang, C. H. Tu*, S. T. Wu*, and H.-T. Wang*, “Dielectric broadband meta-vector-polarizers based on nematic liquid crystal”, APL Photonics 2, 126102 (2017). Featured article. 44. Y. Si, L. J. Kong, Y. N. Li, C. H. Tu*, and H. T. Wang*, “Ghost Imaging with High Visibility Using Classical Light Source,” Chin. Phys. Lett. 3(33), 40-43 (2016). 43. X. Z. Gao, Y. Pan, S. M. Li, D. Wang, Y. Li, C. H. Tu*, and H. T. Wang*, “Vector optical fields broken in the spatial frequency domain,” Phys. Rev. A 93(3), 033834 (2016). 42. M. Q. Cai, P. P. Li, D. Feng, Y. Pan, S. X. Qian, Y. N. Li, C. H. Tu*, and H. T. Wang*, “Microstructures fabricated by dynamically controlled femtosecond patterned vector optical fields,”Opt. Lett. 41(7), 1474-1477 (2016). 41. Y. Pan, X. Z. Gao, M. Q. Cai, G. L. Zhang, Y. N. Li, C. H. Tu, and H. T. Wang*, “Fractal vector optical fields,” Opt. Lett. 41(14), 3161-3164 (2016). 40. Y. Pan, X. Z. Gao, Z. C. Ren, X. L. Wang, C. H. Tu, Y. N. Li*, and H. T. Wang*, “Arbitrarily tunable orbital angular momentum of photons,” Sci. Rep. 6, 29212 (2016). 39. S. M. Li, Z. C. Ren, L. J. Kong, S. X. Qian, C. H. Tu*, Y. Li, and H. T. Wang*, “Unveiling stability of multiple filamentation caused by axial symmetry breaking of polarization,” Photon. Res. 4(5), B29-B34 (2016). 38. P. P. Li, M. Q. Cai, J. Q. Lu, D. Wang, G. G. Liu, S. X. Qian, Y. N. Li, C. H. Tu*, and H. T. Wang*, “Control of femtosecond multi-filamentation in glass by designable patterned optical fields,” AIP Adv. 6(12), 125103 (2016). 37. Y. Pan, Z. C. Ren, S. X. Qian, X. Z. Gao, Y. N. Li, C. H. Tu*, and H. T. Wang*, “Uniformly elliptically-polarizedvector optical fields,” J. Opt. 17, 035616 (2015). 36. X. Z. Gao, Y. Pan, M. Q. Cai, Y. N. Li, C. H. Tu*, and H. T. Wang*, “Hyperbolic-symmetry vector fields,” Opt. Express 23(25), 32238-32252 (2015). 35. Z. C. Ren, L. J. Kong, S. M. Li, S. X. Qian, Y. N. Li, C. H. Tu*, and H. T. Wang*, “Generalized Poincare sphere,” Opt. Express 23(20), 26586-26595 (2015). 34. Z. C. Ren, S. X. Qian, C. H. Tu, Y. N. Li*, and H. T. Wang, “Focal shift in tightly focused Laguerre–Gaussian beams,” Optics Commun. 334, 156-159 (2015). 33. S. M. Li, S. X. Qian, L. J. Kong, Z. C. Ren, Y. Li, C. H. Tu, and H. T. Wang*, “An efficient and robust scheme for controlling the states of polarization in a Sagnac interferometric configuration,” Europhys. Lett. 105(6), 64006 (2014). 32. Y. Li, Z. C. Ren, S. X. Qian, C. H. Tu, and H. T. Wang, “Analytical formulae of tightly focused Laguerre–Gaussian vector fields,” J. Opt. 16(10), 105702 (2014). 31. Y. Pan, Y. N. Li*, S. M. Li, Z. C. Ren, L. J. Kong, C. H. Tu, and H. T. Wang*, “Elliptic-symmetry vector optical fields,” Opt. Express 22(16), 19302-19313 (2014). 30. Y. Pan, Y. Li, Z. C. Ren, Y. Si, C. H. Tu, and H. T. Wang*, “Parabolic-symmetry vector optical fields and their tightly focusing properties,” Phys. Rev. A 89(3), 035801 (2014). 29. S. X. Qian, Y. N. Li*, L. J. Kong, C. H. Tu, and H. T. Wang*, “Phase conjugation of vector fields by degenerate four-wave mixing in a Fe-doped LiNbO3,” Opt. Lett. 39(16), 4907-4910 (2014). 28. S. X. Qian, L. J. Kong, Y. Li, C. H. Tu, and H. T. Wang*, “Recording and reconstruction of vector fields in a Fe-doped LiNbO3 crystal,” Opt. Lett. 39(7), 1917-1920 (2014). 27. S. X. Qian, Y. Li, L. J. Kong, S. M. Li, Z. C. Ren, C. H. Tu, and H. T. Wang*, “Security enhancement of double-random phase encryption by iterative algorithm,” J. Opt. 16(8), 085401 (2014). 26. M. Q. Cai, C. H. Tu*, H. Zhang, S. Qian, K. Lou,Y. Li, and H. T. Wang*, “Subwavelength multiple focal spots produced by tight focusing the patterned vector optical fields,” Opt. Express 21, 31469-31482 (2013). 25. Y. Pan, Y. N. Li, S. M. Li, Z. C. Ren, Y. Si, C. H. Tu, and H. T. Wang*, “Vector optical fields with bipolar symmetry of linear polarization,” Opt. Lett. 38, 3700(2013). 24. Y. Pan, S. M. Li, L. Mao, L. J. Kong, Y. N. Li, C. H. Tu, P. Wang, and H. T. Wang*, “Vector optical fields with polarization distributions similar to electric and magnetic field lines,” Opt. Express 21, 16200 (2013). 23. K. Lou, S. X. Qian, Z. C. Ren, C. H. Tu, Y. N. Li*, and H. T. Wang*, “Femtosecond laser processing by using patterned vector optical fields,” Sci. Rep. 3, 2281; DOI:10.1038/srep02281 (2013). 22. S. M. Li, L. J. Kong, Z. C. Ren, Y. N. Li, C. H. Tu, and H. T. Wang*, “Managing orbital angular momentum in second-harmonic generation”, Phys. Rev. A 88, 035801 (2013). 21. L. J. Kong, Y. N. Li, S. X. Qian, S. M. Li, C. H. Tu, and H. T. Wang*, “Encryption of ghost imaging,” Phys. Rev. A 88, 013852 (2013). 20. K. Lou, S. X. Qian, X. L. Wang, Y. N. Li, B. Gu, C. H. Tu, and H. T. Wang*, “Two-dimensional microstructures induced by femtosecond vector light fields on silicon,” Opt. Express 20, 120 (2012). 19. K. Lou, S. X. Qian, Z. C. Ren, X. L. Wang,Y. N. Li, C. H. Tu, and H. T. Wang*, “Self-formed two-dimensional near-wavelength microstructures on copper induced by multipulse femtosecond vector optical fields,” J. Opt. Soc. Am. B 29, 2282 (2012). 18. Y. N. Li, X. L. Wang, H. Zhao, L. J. Kong, K. Lou, B. Gu, C. H. Tu, and H. T. Wang*, “Young’s two-slit interference of vector light fields,” Opt. Lett. 37, 1790 (2012). 17. S. M. Li, Y. N. Li, X. L. Wang, L. J. Kong, K. Lou, C. H. Tu, Y. J. Tian, and H. T. Wang*, “Taming the Collapse of Optical Fields,” Sci. Rep. 2, 1007; DOI:10.1038/ srep01007 (2012). 16. C. H. Tu, Y. X.Deng, M. Q. Cai, Z. C.Huang, Y. N. Li, F. Y. Lu, and E. B. Li, “Theoretical study on instantaneous linewidth of Fourier-domain mode-locked fiber lasers”, Opt. Comm. 285,5287-5292 (2012). 15. C. H. Tu, Z. C. Huang, S. G. Zhang, M. L. Hu, Q. Y. Wang, E. B. Li, Y. N. Li, and F. Y. Lu*,Second harmonic generation by femtosecond Yb-doped fiber laser source based on PPKTP waveguide fabricated by femtosecond laser direct writing, Opt. Commun. 284, 455-459(2011). 14. C. H. Tu, Z. C. Huang, K. Lou, H. J. Liu, Y. S. Wang, Y. N. Li, F. Y. Lu and H. T. Wang*, “Efficient green-light generation by frequency doubling of a picosecond all-fiber ytterbium-doped fiber amplifier in PPKTP waveguide inscribed by femtosecond laser direct writing”, Opt. Express18,25183-25191(2010). 13. T. Lei, C. H. Tu, F. Y. Lu*, Y. X. Deng, and E. B. Li, “Numerical study on self-similar pulses in modelocking fiber laser by coupled Ginzburg- Landau equation model”, Opt. Express 17(2), 585-591(2009). 12. Y. X. Deng, C. H. Tu, F. Y. Lu, “Study of self-similar pulse nonlinear polarization rotation mode-locked fiber laser”, Acta Physica Sinica, 58(5), 297-302(2009) (In Chinese). 11. J. wang, C. H. Tu, S. G. Zhang, F .Y. Lu*, “Experimental research on Frequency doubling in periodically poled KTiOPO4 waveguide fabricated by femtosecond laser”, Acta Physica Sinica, 59(1),307-310(2010) ) (In Chinese). 10. Z. C. Huang, C. H. Tu, S. G. Zhang, F. Y. Lu*, Y. N. Li, Y. X. Fan, and E. B. Li, “Femtosecond second-harmonic generation in periodically poled lithium niobate waveguides written by femtosecond laser pulses”, Opt. Lett. 35(6), 877-879 (2010). 9. H. Zhu, C. H. Tu, T. Lei, W. G. Guo, Y. N. Li, F. Y. Lu*, X. Y. Dong, D. Wei, “Dual-wavelength narrow-linewidth light source with ultranarrow wavelength spacing based on the pump-induced thermal effects in an Er-Yb-codoped distributed-Bragg-reflector fiber laser”, Opt. Eng. 47(09), 094301(2008). 8. S. G. Zhang, J. H. Yao, W. W. Liu, Z. C. Huang, J. Wang, Y. N. Li, C. H. Tu, F. Y. Lu*, “Second harmonic generation of periodically poled potassium titanyl phosphate waveguide using femtosecond laser pulses”, Opt. Express 16(18), 14180-14185(2008). 7. S. G. Zhang, J. H. Yao, Q. Shi, Y. G. Liu, Y. N. Li, C. H. Tu, W. G. Guo, F. Y. Lu*, “Fibre-Format Photonic Source Based on Efficient Frequency Doubling of Continuous-Wave Erbium-Fibre Laser Amplifier”, Chin. Phys. Lett. 25(8), 2873-2875(2008). 6. C. H. Tu, Z. Li, T. Lei, LI Yong-Nan, Y. N. Li, W. G. Guo, D. Wei, H. Zhu, S. G. Zhang, and F. Y. Lu*, “Pulse Evolution Characteristics in Self-Similar Mode-locked Fibre Laser”, Chin. Phy. Lett. 24(11), 3175-3178(2007). 5. C. H. Tu, W. G. Guo, Y. N. Li, S. G. Zhang, and F. Y. Lu*, “Stable Multiwavelength and Passively Mode-locked Yb-doped Fiber Laser based on Nonlinear Palarization Rotation”, Opt. Commun. 280448-452(2007). 4. Y. N. Li, W. G. Guo, C. H. Tu, T. Lei, T. Ha, D. Wei, and F. Y. Lu*, “Experimental research of wideband and gain-flattened hybrid Raman/erbium-doped fiber amplifier”, Opt. Eng. 46(12), 125004, (2007). 3. 涂成厚,雷霆,李勇男,郭文刚,朱辉,魏岱,吕福云,正常色散光纤放大器中超短脉冲自相似演化条件的研究, 中国激34(11), 1512-1516(2007) 2. 涂成厚,吕福云,李勇男,郭文刚,朱辉,魏岱,雷霆,周寿桓,高能量、无波分裂的超短脉冲光源的研究进展,激光与红外37(11), 304-307(2007) 1. 雷霆,涂成厚,李勇男,郭文刚,魏岱,朱辉,吕福云,高能量无波分裂超短脉冲自相似传输的理论研究和数值模拟, 物理学报56(5), 2769-2775(2007) 申请或授权发明专利 1. 李勇男,娄凯,钱升霞,涂成厚,王慧田,一种飞秒激光直写制备微孔阵列的系统与方法,授权日:2014.12.03,中国,ZL 201310007951.7 2. 涂成厚,蔡孟强,李萍萍,潘岳,李勇男,王慧田,一种基于动态调控的焦场轨迹制作微结构的装置,授权日:2018.1.30,中国,ZL 201510860470.X 3. 涂成厚,蔡孟强,潘岳,戴凡,李勇男,王慧田,一种基于飞秒激光的菲涅尔波带片阵列制作方法及应用,授权日:2019.2.26,中国,ZL 201610720185.2 4. 涂成厚,王珂,王强,张洪爽,李勇男,王慧田,一种矢量贝塞尔光束生成装置, 授权日: 2020.05.22,中国,ZL 201910230839. 7 5. 刘瑞,孔令军,齐文荣,田倩倩,李勇男,涂成厚,王慧田,一种集成化的矢量光场生成器, 授权日: 2020.07.28,中国,ZL 201910096306. 4 6. 刘瑞,齐文荣,孔令军,王周祥,李勇男,涂成厚,王慧田,一种量子螺旋成像系统, 授权日: 2020.07.28,中国,ZL 201910210865.3 7. 涂成厚,蔡孟强,夏正聪,王强,侯喜哲,李勇男,王慧田, 一种微纳结构加工方法及系统, 授权日: 2022.8.2,中国,ZL 202110845915.2 学术交流参加国内外会议 1. Chenghou Tu, Yujia Weng, Zhangchao Huang and Fuyun Lu, “Experimental measurements ofultrashort pulse from an all-normal-dispersion Yb-doped fiberlaser with SHG-FROG using principal component generalized projections algorithm”,Proc.SPIE 7847, 784717 (2010)Asia Photonics 2010 ,October 18 - 20, 2010, Beijing, China 2. Chenghou Tu, Zhangchao Huang and Fuyun Lu, “Frequency Doubling of Femtosecond Yb-doped FiberLaser SourceBased on PPKTP Waveguide Inscribed by Femtosecond Laser Pulses”,POEM2010 (Topic-LTA) The International Photonics and OptoElectronics Meetings, November 3 - 5, 2010, Wuhan, China (Oral Presentation) 3. Chenghou Tu, “Femtosecond vectoroptical field and itsapplications in microfabrication”, The 2nd Russian-Chinese Laser Physics Symposium (RCLPS-2012),October 25- November 1, 2012, Moscow, Russia (Invited Presentation) 4. Chenghou Tu, “Focusing of Patterned Vector Optical Fields and their Applications”, APS March Meeting 2014, March 2-7, 2014, Denver, Corolado, USA (Oral Presentation) 5. Hui-Tian Wang, Chenghou Tu, Mengqiang Cai and Yongnan Li, “Focal fieldregulation of patterned vector optical fields and its application in fabricating micro-structures”,The conference on Advances in Optoelectronics and Micro/nano-optics 2014(AOM2014),September 18-20, 2014, Xian, China (Invited Presentation) 6. Chenghou Tu, Hui-Tian Wang, Mengqiang Cai and Yongnan Li,“Research on femtosecond laser processing by using patterned vector optical fields”, International Conference on Manipulation, Manufacturing and Measurement on theNanoscale 2014 (3M-NANO 2014), October 27-31, 2014, Taipei, China (Invited Presentation) 7. Chenghou Tu, The manipulation of optical field based on spatial light modulator and its applications in micro/nano fabircaitons, The 7th International Conference on Information Optics and Photonics (CIOP 2015), July 12-15, 2015, Nanjing, China (Oral Presentation) 8. Chenghou Tu, “Vector optical field and its applications in micro-fabrication,” The 5th International Symposium on Laser Interaction with Matter (LIMIS2018), Nov. 11-13, 2018, Changsha, China (Oral Presentation) 9.涂成厚,“基于偏振调控的光场新特性与应用”,第二十四届全国激光学术会议暨第十五届全国激光技术与光电子学学术会议(LTO),上海,2020.10.17-20 (邀请报告) 10.Chenghou Tu, “Orbital angular momentum manipulation of vector optical fields and the application in optical micro-manipulation”, The 10th Applied Optics and Photonics China (AOPC 2021), July 23-25, 2021, Beijing, China (Invited Presentation) 11.涂成厚,王强,李勇男,王慧田,“从结构光场调控到光学角动量”,第十七届全国激光技术与光电子学学术会议(LTO2022)暨2022年上海市激光学会学术年会,上海嘉定,2022.8.23-26 (邀请报告) 12. 涂成厚,王强,李勇男,王慧田,“光场焦场的三维定制调控及其应用”,第一届全国光与物质相互作用及其应用大会,哈尔滨,2023年6月2 - 4日(邀请报告) 13.参加中国物理学会秋季学术会议,2009-2019。其中2016年做光物理分会场邀请报告。 社会兼职教学经历本科生课程:大学物理学(上、下册),非物理专业必修课,64学时 研究生课程:非线性光纤光学,博士生选修课,32学时 另外还指导本科生创新项目(百项工程、国创)、本科毕业论文 物理学院2019级本科生班导师 物理学院2023级本科生班导师 荣誉称号1.获武汉市科技进步二等奖一项(排名第五)(2005年) 2.南开大学教学成果二等奖一项(注:集体奖项)(2013) 3.天津市级教学团队(大学物理学基础)成员(2014年) 4.中国物理学会永久会员(2015-) 5.天津市劳动示范集体(物理学术竞赛教学团队)成员(2016年) 6.天津市级教学团队(物理学术竞赛教学团队)成员 (2017年) 7.指导的本科生“国创”项目获南开大学本科生创新科研计划特等奖(2017) 8.指导的本科生毕业论文获天津市“优秀毕业论文”(2017) 9.国家级一流本科课程(线下一流课程)“基本学术能力训练”团队成员(2020) 10. 天津市创新创业教育特色示范课程(基本学术能力训练)团队成员(2022) |