| 职称:教授,博导 | ||||||
办公室:李文正楼北622 | |||||||
办公电话:83793275 | |||||||
Email:wenxuant@seu.edu.cn | |||||||
学习经历: | |||||||
2002/09-2006/06 东南大学 本科 2006/09-2009/03 东南大学 硕士 2009/03-2012/11 伦敦大学玛丽女王学院 博士 | |||||||
工作经历: | |||||||
2012/11-至今东南大学信息科学与工程学院毫米波国家重点实验室 | |||||||
教授课程: | |||||||
电磁场与电磁波 —本科生 电磁材料测量与分析(全英文)—研究生 科技英语写作(全英文) —研究生 | |||||||
研究方向: | |||||||
学科方向:电磁场与微波技术 研究领域:电磁超材料理论和应用研究;人工表面等离激元电路和系统;超材料智能传感器 | |||||||
获奖情况: | |||||||
指导学生获得Best Student Paper Award: 2015 IEEE MTT-S IMWS-AMP 2016年中国光学重要成果奖 东南大学青年教师授课竞赛二等奖(2018) 首批全国高校黄大年式教师团队成员(2018) 东南大学至善青年学者(A类)(2019) 第二届江苏省十佳研究生导师团队成员(2020) 东南大学青年特聘教授(2021) | |||||||
论文著作: | |||||||
出版专著 [1] Tie Jun Cui, Wen Xuan Tang, Wei Xiang Jiang, Zhong Lei Mei and Xin Mi Yang, 《Metamaterials: Beyond Crystals, Noncrystals, and Quasicrystals》, CRC Press,2016 [2] Microwave antennas based on metamaterials and metasurfaces(章节),Tang, Wen Xuan ; Cui, Tie Jun,DEVELOPMENTS IN ANTENNA ANALYSIS AND DESIGN, VOL 1,pp. 407-444, 2018
论文列表 [1] Francisco J. Garcia-Vidal, Antonio I. Fernández-Domínguez, Luis Martin-Moreno, Hao Chi Zhang, Wenxuan Tang, Ruwen Peng, and Tie Jun Cui, “Spoof surface plasmon photonics,” Reviews of Modern Physics (Rev. Mod. Phys.), 94(2), 025004, 2022. [2] Z. Qiu, Y. Xia, B. Wang, Y. Hua, W. Li, W. Tang and T. J. Cui, “A metamaterial based microfluidic sensor for permittivity detection of liquid,” J. Phys. D: Appl. Phys. 55, 435001, 2022. [3] Jiayu Chen, Weihan Li, Yunfeng Zhang, Wenyu Ma, Wenxuan Tang and Tiejun Cui, “Absorption-transmission-type multifunctional coding metasurface,” J. Phys. D: Appl. Phys. 55 (40), 405003, 2022. [4] Yujie Hua, Wenxuan Tang, and Tie Jun Cui, A metamaterial sensor for detecting the location of a sub-wavelength object, Appl. Phys. Lett. 120, 181703 (2022) [5] Wenxuan Tang, Jia Chen, and Tie Jun Cui, “Metamaterial Lenses and Their Applications at Microwave Frequencies,” Advanced Photonics Research, 2100001, 2021. [6] X. T. Yan, W. Tang, J. F. Liu, M. Wang, X. X. Gao, and T. J. Cui, “Glide symmetry for mode control and significant suppression of coupling in dual-strip SSPP transmission lines,” Advanced Photonics (Adv. Photon.), 3(2), 026001, 2021. [7] W. Tang, Y. Hua, and T. J. Cui, “A Compact Component for Multi-Band Rejection and Frequency Coding in the Plasmonic Circuit at Microwave Frequencies,” Electronics, 10(1), 4, 2021. [8] W. Tang, J. Wang, X. Yan, J. Liu, X. Gao, L. Zhang, and T. J. Cui, “Broadband and High-Efficiency Excitation of Spoof Surface Plasmon Polaritons Through Rectangular Waveguide,” Frontiers in Physics, 8, 582692, 2020. [9] J. F. Liu, W. Tang, M. Wang, H. C. Zhang, H. F. Ma, X. Fu, and T. J. Cui, “A Dual-Mode UWB Antenna for Pattern Diversity Application,” IEEE Transaction on Antennas and Propagation, 68(4), 3219-3224, 2020. [10]T. Y. Chen, W. X. Tang, J. Mu and T. J. Cui, “Microwave Metamaterials,” Annalen der Physik (Ann. Phys.), 1800445, 2019. [11]W. X. Tang, H. C. Zhang, H. F. Ma, W. X. Jiang and T. J. Cui, “Concept, Theory, Design, and Applications of Spoof Surface Plasmon Polaritons at Microwave Frequencies,” Advanced Optical Materials, 7, 1800421, 2019. [12]T. Y. Chen, W. X. Tang, J. Mu and T. J. Cui, “Microwave Metamaterials,” Annalen der Physik (Ann. Phys.), 1800445, 2019. [13]W. X. Tang and T. J. Cui, “The engineering way from spoof surface plasmon polaritons to radiations,” EPJ Appl. Metamat., 6, 9, 2019. [14]X. G. Zhang, W. X. Tang, W. X. Jiang, G. D. Bai, J. Tang, L. Bai, C.-W. Qiu, and T. J. Cui, Light-Controllable Digital Coding Metasurfaces, Advanced Science, 1801028, 2018. [15]W. X. Tang, H. C. Zhang, J. F. Liu, J. Xu and T. J. Cui, “Reduction of radiation loss at small-radius bend using spoof surface plasmon polariton transmission line,” Scientific Reports 7, 41077, 2017. [16]汤文轩,张浩驰,崔铁军,人工表面等离激元及其在微波频段的应用,《信息学报》,第39 卷第1 期,2017. [17]W. X. Tang, W. X. Jiang, and T. J. Cui, “Transformation electromagnetics for microwave antennas and radar illusion,” IEEE Antennas and Wireless Propagation Letters, 13, 1792, 2014. [18]W. Tang, R. Yang, and Y. Hao, “Compression of a pyramidal absorber using multiple discrete coordinate transformation,” Optics Express, 22(8), 9033, 2014. [19]B. C. Pan, W. X. Tang, M. Q. Qi, H. F. Ma, Z. Tao and T. J. Cui, “Reduction of the spatially mutual coupling between dual-polarized patch antennas using coupled metamaterial slabs,” Scientific Reports 6, 30288, 2016. [20]L. H. Yuan, W. X. Tang, H. Li, Q. Cheng, and T. J. Cui, “Three-dimensional anisotropic zero-index lenses,” IEEE Transaction on Antennas and Propagation, 62 (8), 4135, 2014. [21]J. Xu, H. C. Zhang, W. X. Tang, J. Guo, C. Qian, and W. Y. Li, “Transmission-spectrum-controllable spoof surface plasmon polaritons using tunable metamaterial particles,” Applied Physics Letters, 108, 191906, 2016. [22]M. Q. Qi, W. X. Tang, H. F. Ma, B. C. Pan, Z. Tao, Y. Z. Sun and T. J. Cui, “Suppressing side-lobe radiations of horn antenna by loading metamaterial lens,” Scientific Reports 5, 9113, 2015. [23]W. Tang, Y. Hao, and R. Mittra, “Design of a carpet cloak to conceal an antenna located underneath,” IEEE Transaction on Antennas and Propagation, 60 (9), 4444, 2012. [24]W. Tang, Y. Hao, and F. Medina, “Broadband extraordinary transmission in a single sub-wavelength aperture,” Optics Express, 18(16), 16946, 2010. [25]W. Tang, C. Argyropoulos, E. Kallos, W. Song, and Y. Hao, “Discrete coordinate transformation for designing all-dielectric flat antennas,” IEEE Transaction on Antennas and Propagation, 58(12), 3795, 2010. | |||||||
科研项目: | |||||||
项目名称 | 项目类别 | 项目时间 | 工作类别 | 项目金额 | |||
基于聚合物先驱体陶瓷的超材料无线无源薄膜传感器设计、制备与测试 | 国家重点研发计划课题(主持) | 2021-2024 | 应用研究 | 226万 | |||
高对称人工表面等离激元超材料的理论及应用 | 国家自然科学基金面上项目(主持) | 2020-2023 | 应用基础研究 | 59万 | |||
微波毫米波数字编码和现场可编程超构材料的理论体系与关键技术 | 国家重点研发计划项目子课题(主持) | 2018-2023 | 应用研究 | 76.71万 | |||
国家自然科学基金青年项目(主持) | 2015-2017 | 应用基础研究 | 25万 | ||||
超宽带超表面技术 | 华为公司创新研究计划项目(主持) | 2021-2022 | 应用研究 | 77.25 | |||
超材料在无限通信频段的应用 | 华为公司创新研究计划项目(主持) | 2014-2015 | 应用研究 | 15万 | |||
人工表面等离激元的调控和应用 | 中央高校基本科研业务费专项(主持) | 2020-2022 | 基础研究 | 30万 | |||
基于人工表面等离激元的微波器件与系统 | 国家自然科学基金重点项目(参与) | 2017-2021 | 基础研究 | 265万 | |||
专利: | |||||||
专利号 | 专利名称 | 专利类型 | |||||
ZL201510387021.8 | 一种基于新型人工电磁材料的电压控制波束可调透镜天线 | 发明专利 | |||||
ZL201310129820.6 | 一种基于人工表面等离激元的插分滤波器 | 发明专利 | |||||
ZL201310190179.7 | 一种基于新型人工电磁材料的宽频带低副瓣透镜天线 | 发明专利 | |||||
ZL201910513560.X | 具有滑移对称特性的人工表面等离激元传输网络 | 发明专利 | |||||
ZL202111020922.5 | 利用半模槽线设计的宽带巴伦滤波器 | 发明专利 | |||||
ZL202011068607.5 | 拉伸可重构人工表面等离激元传输线 | 发明专利 | |||||
