蒋卫祥

发布者:沈如达发布时间:2023-10-25浏览次数:6787

职称:研究员、博导、国家重大人才工程特聘教授

办公室:四牌楼校区李文正楼北622

办公电话:025-83793275

Emailwxjiang81@seu.edu.cn

学习经历:

2000.09 - 2004.07 青岛大学信息与计算科学专业攻读学士学位

2004.09 - 2007.01 tyc234cc 太阳成集团应用数学专业攻读硕士学位

2007.03 - 2010.10 tyc234cc 太阳成集团电磁场与微波技术专业攻读博士学位

工作经历:

2010.11 - 2011.04  tyc234cc 太阳成集团讲师

2011.05 - 2015.04  tyc234cc 太阳成集团副研究员

2015.05 - 至今   tyc234cc 太阳成集团研究员

2017.01 - 至今   tyc234cc 太阳成集团青年首席教授

2018.10 - 2021.09  tyc234cc 太阳成集团江苏特聘教授

2023.08 - 至今    tyc234cc 太阳成集团国家重大人才工程特聘教授

教授课程:

读写能力培养- 本科

基站硬件设计理论与应用- 硕士

电磁场工程的数学基础- 硕士

 

研究方向:

电磁超材料、光调控可编程超表面、天线与电磁波传播、声电超表面

获奖情况:

2011教育部自然科学一等奖(排二)

2013全国优秀博士学位论文

2014国家自然科学二等奖(排三)、国际无线电科学联盟“青年科学家奖”

2015获国家优秀青年基金资助

2016入选国家重大人才工程青年学者

2018国家自然科学奖二等奖(排三)、江苏特聘教授

2020第十七届江苏省青年科技奖

2021中国高等学校十大科技进展(共同完成人)

2022入选国家重大人才工程特聘教授、江苏省优秀博士学位论文指导教师

2023年 首届国际基础科学大会“前沿科学奖”

 

论文著作:

学术专著:

1.          Jiang W. X. and Cui T. J.  “Chapter 2: Optical Transformation Theory”   in Metamaterials - Theory, Design, and Applications, Springer,   2009.

2.          Cui T. J., Tang W. X., Yang X. M., Mei Z.   L. and Jiang W. X.Metamaterials:   Beyond Crystals, Noncrystals, and Quasicrystals. CRC Press, 2016.

3.          蒋卫祥, 崔铁军. 变换光学理论及其应用. 北京: 国防工业出版社,   2016.

4.          Jiang W. X., Mei Z. L. and Cui T. J.Effective Medium Theory of Metamaterials and Metasurfaces. Cambridge   University Press, 2022.

期刊论文:

1.        Zhang X. G., Jiang W. X.*, Jiang H. L., Wang Q., Tian H. W., Bai L.,   Luo Z. J., Sun S., Luo Y., Qiu C.-W. and Cui T. J., An optically driven digital metasurface for   programming electromagnetic functions,” Nature Electronics, vol.3, pp.   165-171, 2020.

2.        Jiang W. X., Qiu C.-W., Han T. C., Cheng Q., Ma H. F.,   Zhang S. and Cui T. J., Broadband   all-dielectric magnifying lens for far-field high-resolution imaging,” Advanced   Materials, vol. 25, pp. 6963-6968, 2013.

3.        Zhang X. G., Sun Y. L., Yu Q., Cheng Q., Jiang W. X.*,   Qiu C.-W. and Cui T. J, Smart   Doppler cloak operating in broad band and full polarizations,” Advanced   Materials, vol. 33, No. 2007966, 2021.

4.        Jiang W. X., Luo C. Y., Ge S., Qiu C.-W. and Cui T. J,   An optically controllable transformation-dc   illusion device,” Advanced Materials, vol. 27, pp. 4628-4633, 2015.

5.        Zhang X. G., Sun Y. L., Zhu B., Jiang W. X.*,   Yu Q., Tian H. W., Qiu C.-W., Zhang Z. and Cui T. J., A metasurface-based light-to-microwave   transmitter for hybrid wireless communications,” Light-Science &   Applications, vol.11, No. 126, 2022.

6.        Jiang W. X., Chin J. Y. and Cui T. J, Anisotropic metamaterial devices,” Materials   Today, vol. 12, pp. 26-33, 2009.

7.        Jiang W. X., Qiu C.-W., Han T., Zhang S. and Cui T.   J., Creation of ghost illusions using wave   dynamics in metamaterials,” Advanced Functional Materials, vol. 23,   pp. 4248-4034, 2013.

8.        Xu P., Tian H. W., Cai X., Jiang W. X.*and Cui T. J, Radiation-type metasurfaces for advanced   electromagnetic manipulation,” Advanced Functional Materials, vol. 31,   No. 2100569, 2021.

9.        Tian H. W., Zhang X. G., Jiang W. X.*,   Li X., Liu Y. K., Qiu C.-W. and Cui T. J., Programmable controlling of multiple   spatial harmonics via a nonlinearly-phased grating metasurface,” Advanced   Functional Materials, vol. 32, No. 2203120, 2022.

10.  Tian   H. W., Xu L., Li X., Jiang W. X.* and Cui T. J., Integrated control of radiations and in-band   co-polarized reflections by a single programmable metasurface,” Advanced   Functional Materials, vol. 33, No. 2302753, 2023.

11.  Jiang W. X., Ge S., Han T., Zhang   S., Mehmood M. Q., Qiu C.-W. and Cui T. J., Shaping 3d path of electromagnetic waves   using gradient-refractive-index metamaterials,” Advanced Science, vol.   3, No.  1600022, 2016.

12.  Zhang   X. G., Tang W. X., Jiang W. X.*, Bai G. D., Tang J., Bai L., Qiu C.-W. and   Cui T. J, Light-controllable digital coding   metasurfaces,” Advanced Science, vol. 5, No. 1801028, 2018.

13.  Zhang   X. G., Yu Q., Jiang W. X.*, Sun Y. L., Bai L., Wang Q., Qiu C.-W. and   Cui T. J., Polarization-controlled dual-programmable   metasurfaces,” Advanced Science, vol. 7, No. 1903382, 2020.

14.  Sun   Y. L., Zhang X. G., Yu Q., Jiang W. X.*and   Cui T. J., Infrared-controlled programmable   metasurface,” Science Bulletin, vol. 65, pp. 883-888, 2020.

15.  Zhang   X. G., Sun Y. L., Zhu B., Jiang W. X.*, Zhang Z. and Cui T. J., Light-controllable time-domain digital   coding metasurfaces,” Advanced Photonics, vol.4, No. 025001, 2022.

16.  Bai.   L., Liu Y. K., Xu, L., Zhang Z., Wang Q.,Jiang W. X.*,   Qiu C. W. and Cui T. J., A   smart metasurface for electromagnetic manipulation based on speech   recognition,” Engineering, vol. 22, pp. 185-190, 2023.

17.  Jiang W. X., Cui T. J., Zhou X. Y.,   Yang X. M. and Cheng Q., Arbitrary bending of electromagnetic waves using realizable   inhomogeneous and anisotropic materials,Physical Review   E, vol.78, No. 066607, 2008.

18.  Jiang W. X., Cui T. J., Yang X. M.,   Cheng Q., Liu R. and Smith D. R., Invisibility   cloak without singularity,” Applied Physics Letters, vol. 93, No. 194102, 2008.  

19.  Jiang W. X., Cui T. J., Ma H. F.,   Zhou X. Y. and Cheng Q., Cylindrical-to-plane-wave   conversion via embedded optical transformation,” Applied Physics Letters,   vol. 92, No. 261903, 2008.

20.  Jiang W. X., Cui T. J., Ma H. F.,   Yang X. M. and Cheng Q., Layered   high-gain lens antennas via discrete optical transformation,” Applied   Physics Letters, vol. 93, No. 221906,2008.

21.  Jiang W. X., Cui T. J., Cheng Q.,   Chin J. Y., Yang X. M., Liu R. and Smith D. R., Design of arbitrarily shaped concentrators   based on conformally optical transformation of nonuniform rational B-spline   surfaces,” Applied Physics Letters, vol. 92, No. 264101, 2008.

22.  Jiang W. X., Ma H. F., Cheng Q. and   Cui T. J, Illusion media: Generating virtual objects   using realizable metamaterials,” Applied Physics Letters, vol. 96, No.   121910, 2010.

23.  Jiang W. X., Ma H. F., Cheng Q. and   Cui T. J, A class of line-transformed cloaks with   easily realizable constitutive parameters,” Journal of Applied Physics,   vol. 107, No. 034911, 2010.

24.  Jiang W. X., Cui T. J., Yang X. M.,   Ma H. F. and Cheng Q, Shrinking   an arbitrary object as one desires using metamaterials,” Applied Physics   Letters, vol. 98, No. 204101, 2011.

25.  Jiang W. X.and Cui T. J, Radar illusion via metamaterials,” Physical   Review E, vol. 83, No. 026601, 2011.

26.  Jiang W. X., Luo C. Y., Mei Z. L.   and Cui T. J., An   ultrathin but nearly perfect direct current electric cloak,” Applied   Physics Letters, vol. 102, No. 014102, 2013.

27.  Jiang W. X., Ge S., Luo C. and Cui   T. J., Localized transformation optics devices,” Applied   Physics Letters, vol. 103, No. 214104, 2013.

28.  Xu   B. B., Jiang W. X.*,   Meng L. L. and Cui T. J, Transmitting   information of an object behind the obstacle to infinity,” Scientific   Reports, vol. 5, No.13140,   2015.

29.  Jiang W. X., Bao D. and Cui T. J., Designing novel anisotropic lenses with   transformation optics,” Journal of Optics, vol.18, 044022, 2016.

30.  Zhang   X. G., Jiang W. X.*and Cui T. J, Frequency-dependent transmission-type   digital coding metasurface controlled by light intensity,” Applied Physics   Letters, vol. 113, No. 091601, 2018.    

31.  Xu   P., Jiang W. X.*,   Wang S. Y. and Cui T. J, An   ultrathin cross-polarization converter with near unity efficiency for   transmitted waves,” IEEE Transactions on Antennas and Propagation,   vol. 66, pp. 4370-4373, 2018.

32.  Tao   Z., Jiang W. X.,   Ma H. F. and Cui T. J, High-gain   and high-efficiency grin metamaterial lens antenna with uniform amplitude and   phase distributions on aperture,” IEEE Transactions on Antennas and   Propagation, vol. 66, pp. 16-22, 2018. (共同一作)

33.  Bai   L., Dong H. Y., Song G. Y., Cheng Q., Huang B., Jiang W. X.*and   Cui T. J, Impedance-matching wavefront-transformation   lens based on acoustic metamaterials,” Advanced Materials Technologies,   vol. 3, No. 1800064, 2018.

34.  Zhang   X. G., Jiang W. X.*,   Tian H. W. and Cui T. J, Controlling   radiation beams by low-profile planar antenna arrays with coding elements,”   ACS Omega, vol. 3, pp. 10601-10611, 2018.

35.  Zhang   N., Jiang W. X.*,   Ma H. F., Tang W. X. and Cui T. J., Compact   high-performance lens antenna based on impedance-matching gradient-index   metamaterials,” IEEE Transactions on Antennas and Propagation, vol.   67, pp. 1323-1328, 2019.

36.  Wang   Q., Zhang X. G., Tian H. W., Jiang W. X.*, Bao D., Jiang H. L., Luo Z. J., Wu L. T.   and Cui T. J., Millimeter-wave   digital coding metasurfaces based on nematic liquid crystals,” Advanced   Theory and Simulations, vol. 2, No. 1900141, 2019.

37.  Bai   L., Song G. Y., Jiang W. X.*, Cheng Q. and Cui T. J., “Acoustic tunable   metamaterials based on anisotropic unit cells,” Applied Physics Letters,   vol. 115, No. 231902, 2019.

38.  Tian   H. W., Jiang W. X.*,   Li X., Zhang X. G., Yang Z. Y. and Cui T. J., “Generation of high-order   orbital angular momentum beams and split beams simultaneously by employing   anisotropic coding metasurfaces,” Journal of Optics, vol. 21, No. 065103,   2019.

39.  Zhang   X. G., Jiang W. X.*,   Tian H. W., Wang Z. X., Wang Q. and Cui T. J., “Pattern-reconfigurable planar   array antenna characterized by digital coding method,” IEEE Transactions   on Antennas and Propagation, vol. 68, pp.1170-1175, 2020.

40.  Xu   P., Jiang W. X.*,   Cai X., Bai S. H. and Cui T. J., “An integrated coding-metasurface-based   array antenna,” IEEE Transactions on Antennas and Propagation, vol.   68, pp. 891-899, 2020.

41.  Bao   J. X., Liu N., Tian H. W., Wang Q., Cui T. J., Jiang W. X.*, Zhang S. and Cao T., “Chirality   enhancement using Fabry-Perot-like cavity,” Research, vol. 2020, No. 7873581,   2020.

42.  Wang   Q., Tian H. W., Jiang W. X.*, Chen M. Z., Zhang X. G. and Cui T. J.,   “An ultrawideband and dual-beam scanning array antenna charactered by coding   method,” IEEE Antennas and Wireless Propagation Letters, vol.19, pp.   2211-2215, 2020.

43.  Tian   H. W., Shen H. Y., Zhang X. G., Li X., Jiang W. X.*. and Cui T. J., “Terahertz Metasurfaces:   toward multifunctional and programmable wave manipulation,” Frontiers in   Physics, vol. 8, No. 584077, 2020.

44.  Xu   P., Tian H. W., Jiang W. X.*, Chen Z. Z., Cao T., Qiu C.-W. and Cui T.   J, “Phase and polarization modulations using radiation-type metasurfaces,” Advanced   Optical Materials, vol. 9, No. 2100159,   2021.

45.  Yu,   Q., Zheng Y. N., Gu Z., Liu J., Liang Y. C., Li L. Z., Zhang X. G. and Jiang W. X,* “Self-adaptive   metasurface platform based on computer vision,” Optics Letters, vol.   46, pp. 3520-3523, 2021.

46.  Tian   H. W., Jiang W. X.*,   Li X., Chen Z. P. and Cui T. J, “An ultrawideband and high-gain antenna based   on 3-d impedance-matching metamaterial lens,” IEEE Transactions on   Antennas and Propagation, vol. 69, pp. 3084-3093, 2021.

47.  Zhang   Z., Jiang W. X.*, Zhang X. G., Cao W. K., Bai L., Qiu C.-W.   and Cui T. J., “Efficient digital metasurfaces for full-space manipulation of   acoustic waves with low crosstalk between reflection and transmission,” Material   & Design, vol. 229, No. 111903, 2023.

48.  Xu   L., Wang D. Y., Zhang X. G., Bai L.,Jiang W. X.* and   Cui T. J., “Cloud-connected networked metasurfaces for online electromagnetic   manipulations,” ACS Photonics, vol. 10, pp.1558–1565, 2023.

49.  Zhang   X. G., Sun Y. L., Zhu B., Wang J., Zhao T., Huang Z. X. Jiang W. X.*,   Huang Z., Zhang Z. and Cui T. J., “Optoelectronic metasurface for free-space optical-microwave   interactions,” ACS Appl. Mater. Interfaces, 1vol. 5, pp. 22744−22751,   2023.

50.  Zhang   X. G., Sun Y. L., Huang Z. X. and Jiang W. X.*, “A   review of light-controlled programmable metasurfaces for remote microwave   control and hybrid signal processing,” Engineering Report, vol. 5, No.   e123658, 2023.

 

科研项目:

项目名称

项目类别

项目时间

工作类别

项目金额

新型幻觉光学器件的机理分析和实验验证

国家自然科学基金面上项目

2012.01-2015.12

应用基础研究

63

新型人工电磁媒质

国家优秀青年基金

2016.01-2018.12

应用基础研究

150

基于超材料的***研究与优化

GF合作项目

2020.08-2023.11

应用基础研究

165

***

173重点项目课题

2022.08-2026.08

应用基础研究

420

可编程超表面和量子编码超表面

tyc234cc 太阳成集团中央高校优秀青年团队项目

2023.01-2024.12

应用基础研究

400

专利:

专利号

专利名称

专利类型

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发明专利

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一种双通道独立可编程超表面及其控制方法

发明专利

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一种基于液晶双机制高灵敏毫米波超表面传感器

发明专利

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发明专利

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发明专利

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发明专利

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一种高效平面电磁波极化转换器

发明专利

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一种可集成低剖面数字编码天线

发明专利

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一种C波段有源人工电磁表面

发明专利

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口径面相位和幅度均匀分布的高增益透镜天线

发明专利

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基于人工表面等离激元的紧凑型闭环谐振器

发明专利

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基于渐变折射率超材料的天线罩

发明专利

CN201510540698.0

一种光调控直流变换器件

发明专利

CN201410401944.X

一种基于超材料的折射率梯度平板聚焦透镜

发明专利

CN201410228367.9

一种三维放大透镜

发明专利

CN200810155900.8

基于光学变换理论的高增益分层透镜天线

发明专利