入选人才计划项目：

●国家优秀青年科学基金项目。

●教育部“新世纪优秀人才支持计划”。 

●天津市“131”创新型人才培养工程第一层次人选。

●南开大学百名青年学科带头人培养计划。 

作为负责人主持科研项目：

●国家973计划项目课题“介观光学及局域场调控理论研究”。

●国家自然科学基金项目"非经典电磁边界条件下金属纳米谐振结构的准简正模式理论研究"。

●国家自然科学基金项目“表面等离激元自发辐射增强效应中准简正模式形成机理研究”。

●国家自然科学基金项目“金属纳米间隙复合型表面等离激元自发辐射耦合增强效应研究”。

●国家自然科学基金项目“亚波长金属孔径阵列透射增强的微观模型与性能控制研究”。     

●教育部高等学校科技创新工程重大项目培育资金项目“金属亚波长阵列拉曼传感器电磁增强的理论分析与设计”。

●天津市应用基础及前沿技术研究计划重点项目“微纳米金属结构实现表面增强拉曼光谱传感的机理研究”。     

●国家973计划项目课题子课题“金属亚波长结构理论及其表面增强拉曼光谱技术”。     

●天津市自然科学基金项目“用于双光子荧光扫描显微术的超分辨衍射器件的研究”。

发表SCI期刊论文90余篇（其中第一或通讯作者60余篇），包括Nature 2篇（第一作者1篇，影响因子50.5），Physical Review Letters 3篇（影响因子8.1），Optica出版集团（前美国光学学会）刊物Spotlight、封面文章各1篇，SCI引用2500余次。在国际学术会议作特邀报告20余次，并多次担任分会主席、技术委员会成员和分会召集人。

●Qiyong Tao, Yuhang Su, Can Tao, Ying Zhong, Haitao Liu* (*代表通讯作者). Efficient method for modeling large-scale arrays of optical nanoresonators based on the coupling theory of quasinormal mode. Optics Express, 2024, Vol. 32 (No. 5), pp. 7171-7184.

●Xiaoyang Lu, Qiyong Tao, Ying Zhong*, Haitao Liu*. Efficient method for the electrodynamics Langevin-dynamics simulation of multiple nanoparticles based on the coupling theory of quasinormal mode. ACS Photonics, 2024, Vol. 11 (No. 8), pp. 2970-2980.

●Qiyong Tao, Sheng Rong, Ying Zhong, Haitao Liu*. Long-range and rapid trapping of nanoobjects via a combined optical-force and photothermal-convection effect. Optics and Lasers in Engineering, 2024, Vol. 176, pp. 108093.

●Junda Zhu, Changqing Wang, Can Tao, Zhoutian Fu, Haitao Liu*, Fang Bo*, Lan Yang*, Guoquan Zhang*, Jingjun Xu*. Local chirality at exceptional points in optical whispering-gallery microcavities. Physical Review A (Letter), 2023, Vol. 108 (No. 4), pp. L041501.

●Can Tao, Ying Zhong, Haitao Liu*. Quasinormal mode expansion theory for mesoscale plasmonic nanoresonators: an analytical treatment of nonclassical electromagnetic boundary condition. Physical Review Letters, 2022, Vol. 129 (No. 19), pp. 197401.

●Pingzhun Ma, Qiyong Tao, Zhe Qi, Yuhang Su, Ying Zhong, Haitao Liu*. Remote two-dimensional nanometric localization of molecules by the analysis of fluorescence coupled to guided surface plasmons. Journal of Materials Chemistry C, 2022, Vol. 10 (No. 19), pp. 7651-7661.

●Pingzhun Ma, Junda Zhu, Ying Zhong, Haitao Liu*. Theories of indirect chiral coupling and proposal of Fabry-Perot resonance as a flexible chiral-coupling interface. Photonics Research, 2022, Vol. 10 (No. 4), pp. 1071-1089.

●Ning Wang, Ying Zhong, Haitao Liu*. Spontaneous emission enhancement by rotationally-symmetric optical nanoantennas: impact of radially and axially propagating surface plasmon polaritons. Optics Express, 2022, Vol. 30 (No. 8), pp. 12797-12822.

●Zhe Qi, Can Tao, Sheng Rong, Ying Zhong, Haitao Liu*. Efficient method for the calculation of the optical force of a single nanoparticle based on the quasinormal mode expansion. Optics Letters, 2021, Vol. 46 (No. 11), pp. 2658-2661.

●Zhe Qi, Ying Zhong, Haitao Liu*. Efficient method for the calculation of the optical force of multiple nanoparticles based on the coupling theory ofquasinormal modes. Optics Letters, 2021, Vol. 46 (No.18), pp. 4610-4613.

●Haitao Liu*. Coordinate transformation method for modeling three-dimensional photonic structures with curved boundaries. Optics Express, 2021, Vol. 29 (No. 2), pp. 1516-1531.

●Xuelin Zhai, Ning Wang, Ying Zhong, Haitao Liu*. Broadband enhancement of the spontaneous emission by a split-ring nanoantenna: impact of azimuthally propagating surface plasmon polaritons. IEEE Journal of Selected Topics in Quantum Electronics (invited), 2021, Vol. 27(No. 1), pp. 4600815.

●Can Tao, Junda Zhu, Ying Zhong, Haitao Liu*. Coupling theory of quasinormal modes for lossy and dispersive plasmonic nanoresonators. Physical Review B, 2020, Vol. 102 (No. 4), pp. 045430.

●Junda Zhu, Haitao Liu*, Fang Bo*, Can Tao, Guoquan Zhang*, Jingjun Xu*. Intuitive modelof exceptional points in an optical whispering-gallery microcavity perturbed by nanoparticles. Physical Review A, 2020, Vol. 101 (No. 5), pp. 053842.

●Huayu Wang, Yu Lin, Pingzhun Ma, Ying Zhong, Haitao Liu*. Tunable fluorescence emission of molecules with controllable positions within the metallic nano-gap between gold nano-rods and gold film. Journal of Materials Chemistry C, 2019, Vol. 7 (No. 43), pp. 13526-13535.

●Junda Zhu, Tong Zhu, Hongwei Jia, Ying Zhong, Haitao Liu*. Intuitive analysis of subwavelength plasmonic trench waveguide. Journal of Lightwave Technology, 2019, Vol. 37 (No.4), pp. 1345-1351.

●Ying Zhong, Fuping Sun, Haitao Liu*. Impact of propagative surface plasmon polaritons on the electromagnetic enhancement by localized gap surface plasmons between metallic nanoparticles and substrate. Plasmonics, 2019, Vol. 14 (No. 6), pp.1393-1403.

●Huigang Liu*, Lu Zheng, Pingzhun Ma, Ying Zhong, Bo Liu, Xianzhong Chen*, Haitao Liu*. Metasurface generated polarization insensitive Fano resonance for high performance refractive index sensing. Optics Express, 2019, Vol. 27 (No. 9), pp. 13252-13262.

●Jianing Wan, Junda Zhu, Ying Zhong, Haitao Liu*. Semianalytical model for the electromagnetic enhancement by a rectangular nanowire optical antenna on metallic substrate. Journal of the Optical Society of America A, 2018, Vol. 35 (No. 6), pp. 880-889.

●Junda Zhu, Ying Zhong, Haitao Liu*. Impact of nanoparticle-induced scattering of an azimuthally propagating mode on the resonance of whispering gallery microcavities. Photonics Research, 2017, Vol. 5 (No. 5), pp. 396-405.

●Hongwei Jia, Fan Yang, Ying Zhong, Haitao Liu*. Understanding localized surface plasmon resonance with propagative surface plasmon polaritons in optical nanogap antennas. Photonics Research (cover story), 2016, Vol. 4 (No. 6), pp. 293-305.

●Hongwei Jia, Philippe Lalanne, Haitao Liu*. Comprehensive surface-wavedescription for the nano-scale energy concentration with resonant dipole antennas. Plasmonics, 2016, Vol. 11 (No. 4), pp.1025-1033.

●Fan Yang, Haitao Liu*, Hongwei Jia, Ying Zhong. Analytical description of quasi-normal mode in resonant plasmonic nano cavities. Journal of Optics, 2016, Vol. 18 (No. 3), pp. 035003.

●Hongwei Jia, Yunya Xie, Haitao Liu*, Ying Zhong. Analytical model for the excitation of leaky surface plasmon polaritons in the attenuated total reflection configuration. Journal of Optics, 2016, Vol. 18 (No. 5), pp. 055003.

●Junda Zhu, Haitao Liu*, Ying Zhong. Treatmentof nonconvergence of the Fourier modal method and C method arising from field hypersingularities at lossless metal–dielectric arbitrary-angle edges. Journal of the Optical Society of America A, 2016, Vol. 33 (No. 5), pp. 845-853.

●J. B. Wu, X. Zhang, B. B. Jin*, Haitao Liu*, Y. H. Chen, Z. Y. Li, C. H. Zhang, L. Kang, W. W. Xu, J. Chen, H. B. Wang, M. Tonouchi, P. H. Wu*. The dynamic process and microscopic mechanism of extraordinary terahertz transmission through perforated superconducting films. Scientific Reports, 2015, Vol. 5, pp. 15588.

●Hongwei Jia, Haitao Liu*, Ying Zhong. Role of surface plasmon polaritons and other waves in the radiation of resonant optical dipole antennas. Scientific Reports, 2015, Vol. 5, pp. 8456.

●Yunya Xie, Haitao Liu*, Hongwei Jia, Ying Zhong. Surface-mode model of the extraordinary optical transmission without plasmons. Optics Express, 2015, Vol. 23 (No. 5), pp. 5749-5762.

●Chuan Liu, Haitao Liu*, Ying Zhong. Impact of surface plasmon polaritons and other waves on the radiation of a dipole emitter close to a metallic nanowire antenna. Optics Express, 2014, Vol. 22 (No. 21), pp. 25539-25549.

●Ying Li, Haitao Liu*, Hongwei Jia, Fang Bo, Guoquan Zhang, Jingjun Xu. Fully vectorial modeling of cylindrical microresonators with aperiodic Fourier modal method. Journal of the Optical Society of America A, 2014, Vol. 31 (No. 11), pp. 2459-2466.

●Xin Zhang, Haitao Liu*, Ying Zhong. Microscopic analysis of surface Bloch modes on periodically perforated metallic surfaces and their relation to extraordinary optical transmission. Physical Review B, 2014, Vol. 89 (No. 19), pp.195431.

●Yanpeng Mei, Haitao Liu*, Ying Zhong. Treatment of nonconvergence of Fourier modal method arising from irregular field singularities at lossless metal-dielectric right-angle edges. Journal of the Optical Society of America A, 2014, Vol. 31 (No. 4), pp. 900-906.

●Haitao Liu*. Coherent-form energy conservation relation for the elastic scattering of a guided mode in a symmetric scattering system. Optics Express, 2013, Vol. 21 (No. 20), pp. 24093-24098.

●Xin Zhang, Haitao Liu*, Ying Zhong. Large-area electromagnetic enhancement by a resonant excitation of surface waves on a metallic surface with periodic subwavelength patterns. Optics Express, 2013, Vol. 21 (No. 20), pp. 24139-24153.

●Haitao Liu*, Philippe Lalanne. General properties of the surface charge pattern of one-dimensional metallic gratings. Optics Express, 2013, Vol. 21 (No. 14), pp. 16753-16762.

●Zhiwen Zeng, Haitao Liu*. Electromagnetic enhancementby a T-shaped metallic nanogroove: impact of surface plasmon polaritons and other surface waves. IEEE Journal of Selected Topics in Quantum Electronics, 2012, Vol. 18 (No. 6), pp. 1669-1675.

●Xin Zhang, Haitao Liu*, Ying Zhong. Compensation of propagation loss of surface plasmon polaritons with a finite-thickness dielectric gain layer. Journal of Optics, 2012, Vol. 14 (No. 12), pp. 125003.

●Siwen Zhang, Haitao Liu*, Guoguang Mu. Electromagnetic enhancement by a periodic array of nanogrooves in a metallic substrate. Journal of the Optical Society of America A, 2011, Vol. 28 (No. 5), pp. 879-886.

●Haitao Liu*, Philippe Lalanne. Light scattering by metallic surfaces with subwavelength patterns. Physical Review B, 2010, Vol. 82 (No. 11), pp. 115418.

●Haitao Liu*, Philippe Lalanne. Comprehensive microscopic model of the extraordinary optical transmission. Journal of the Optical Society of America A (Spotlight), 2010, Vol. 27 (No. 12), pp. 2542-2550.

●Haitao Liu*. Symmetry in the elementary scattering of surface plasmon polaritons and a generalized symmetry principle. Optics Letters, 2010, Vol. 35 (No. 17), pp. 2876-2878.

●Siwen Zhang, Haitao Liu*, Guoguang Mu. Electromagnetic enhancement by a single nano-groove in metallic substrate. Journal of the Optical Society of America A, 2010, Vol. 27 (No. 7), pp. 1555-1560.

●Haitao Liu, Philippe Lalanne*, Xiaoyan Yang, Jean-Paul Hugonin. Surface plasmon generation by subwavelength isolated objects. IEEE Journal of Selected Topics in Quantum Electronics, 2008, Vol. 14 (No. 6), pp. 1522-1529.

●Haitao Liu, Philippe Lalanne*. Microscopic theory of the extraordinary optical transmission. Nature, 2008, Vol. 452 (No. 7188), pp. 728-731.

●Frerik van Beijnum*, Chris Retif, Chris B. Smiet, Haitao Liu, Philippe Lalanne, Martin P. van Exter. Quasi-cylindrical wave contribution in experiments on extraordinary optical transmission. Nature, 2012, Vol. 492 (No. 7429), pp. 411-414.