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现代天线研究所Modern Antenna Research Center
.01

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上海交通大学,电信群楼1号楼,523房间
weiren.zhu@sjtu.edu.cn
+86-21-3420 8587
上海交通大学,电信群楼1号楼,523房间

简介

Chinese

朱卫仁,博士,特别研究员、博士生导师。2006年和2011在西北工业大学分别获得学士和博士学位, 2011年7月至2012年1月在澳大利亚国立大学做博士后(Postdoctoral Fellow),2012年4月至2016年4月在澳大利亚莫纳什大学任博士后研究员(Reseach Fellow)。2016年4月加入上海交通大学,现任电子信息与电气工程学院电子工程系特别研究员,同时为澳大利亚莫纳什大学客座高级研究员(Adjunct Senior Research Fellow)。朱卫仁博士研究方向包括人工电磁超材料的理论及实现、基于超材料的天线及射频器件、表面等离子体激元等。目前已发表SCI 收录的期刊论文90余篇,被引用1400余次,H-index为23。担任国际期刊IEEE Photonics Journal副编辑,Journal of Physics: Condensed Matter(SCI刊源)客座编辑,International Journal of Antennas and Propagation(SCI刊源)客座主编,以及Frontier in Physics (ESCI刊源)编委,同时为OSA、IEEE等协会旗下20余种期刊的通讯审稿人。

About

English

Weiren ZHU, Ph.D, Associate Professor Dr. Zhu received his bachelor’s and PhD degrees from Northwestern Polytechnical University in 2006 and 2011, respectively. After that, he was a postdoctoral fellow at the Nonlinear Physics Centre, Australian National University. From 2012 to 2016, he was a research fellow at the Advanced Computing and Simulation Laboratory, Monash University. He is currently an Associate Professor in the Department of Electronic Engineering at Shanghai Jiao Tong University. He is also an adjunct senior research fellow in the Department of Electrical and Computer Systems Engineering at Monash University. He has published/co-published over 90 journal papers and 30 patents. His research interests include theory, modeling and numerical analysis of electromagnetic waves in metamaterials, metamaterial based antennas and RF devices, and surface plasmon polaritons.
近期动态

  实验室教师和学生赴美国圣地亚哥参加APS/URSI2017会议(2017 IEEE AP-S Symposium on Antennas and Propagation and USNC-URSI Radio Science Meeting,San Diego, California, USA),并与Professor Richard W. Ziolkowski合影留念。


从左往右分别为:朱卫仁耿军平Richard W. Ziolkowski金荣洪、贺冲、姚羽、梁仙灵
.02

RESUME

Education
  • 2002.09
    2006.07
    Xi'an

    Bachelor

    Northwestern Polytechnical University

    Department of Applied Physics, Northwestern Polytechnical University, Xi'an, P. R. China
  • 2006.09
    2011.07
    Xi'an

    Ph. D

    Northwestern Polytechnical University

    Department of Applied Physics, Northwestern Polytechnical University, Xi'an, P. R. China
ACADEMIC AND PROFESSIONAL POSITIONS
  • 2011.07
    2012.01
    Canberra

    Postdoctoral Fellow

    Australian National University

    Postdoctoral Fellow Nonliner Physics Centre, Research School of Physical Science and Engineering, Australian National University, Canberra, Australia
  • 2012.04
    2016.04
    Melbourne

    Research Fellow

    Monash University

    Research Fellow Department of Electrical and Computer Systems Engineering, Monash University, Clayton, Australia
  • 2016.04
    NOW
    Shanghai

    Associate Professor (特别研究员)

    Shanghai Jiao Tong Universtiy

    Associate Professor (特别研究员) Modern Antenna Research Center Department of Electronic Engineering, Shanghai Jiao Tong Universtiy, Shanghai, P. R. China
  • 2016.08
    NOW
    Melbourne

    Adjunct Senior Research Fellow

    Monash University

    Adjunct Senior Research Fellow, Department of Electrical and Computer Systems Engineering, Monash University, Clayton, Australia
.03

RESEARCH

Research

METAMATERIALS & METASURFACES

Metamaterials (from the Greek word μετά meta, meaning “beyond”) are a kind of artificial material engineered to have properties that are not found in nature. They are made from assemblies of multiple elements fashioned from composite materials such as metals or dielectrics. The materials are usually arranged in repeating patterns, at scales that are significantly smaller than the wavelengths of the phenomena they influence. Metamaterials derive their properties from their newly designed structures rather than the properties of the base materials. Their precise shape, geometry, size, orientation and arrangement give them smart properties capable of manipulating electromagnetic waves by blocking, absorbing, enhancing, or bending waves, to achieve benefits that go beyond what is possible with conventional materials.

Appropriately designed metamaterials can affect waves of electromagnetic radiation in a manner not observed in bulk materials. Potential applications of metamaterials are diverse and include optical/electromagnetic filters, medical devices, remote aerospace applications, sensor detection and infrastructure monitoring, smart solar power management, crowd control, high-frequency battlefield communication, and lenses for high-gain antennas. The research of metamaterials is interdisciplinary and involves such fields as electrical engineering, electromagnetics, classical optics, solid state physics, microwave and antenna engineering, optoelectronics, material sciences, nanoscience and semiconductor engineering.

METAMATERIAL ANTENNAS

Metamaterial antennas are a class of antennas which use metamaterials for enhancing the performances of antenna systems, including miniaturization, gain,  directionality, et al. Their purpose, as with any electromagnetic antenna, is to launch energy into free space. However, this class of antenna incorporates metamaterials, which are materials engineered with novel, often microscopic, structures to produce unusual physical properties. Antenna designs incorporating metamaterials can step-up the antenna's radiated power. Conventional antennas that are very small compared to the wavelength reflect most of the signal back to the source. A metamaterial antenna behaves as if it were much larger than its actual size, because its novel structure stores and re-radiates energy. Established lithography techniques can be used to print metamaterial elements on a PC board.These novel antennas aid applications such as portable interaction with satellites, wide angle beam steering, emergency communications devices, micro-sensors and portable ground-penetrating radars to search for geophysical features. Some applications for metamaterial antennas are wireless communication, space communications, GPS, satellites, space vehicle navigation and airplanes.

PLASMONICS & NANO ANTENNAS

In metals, light can couple to electrons to form a wave that is bound to the surface of the metal. This wave is called the surface plasmon. The surface plasmon mode is generally characterized by intense fields that decay quickly away from the interface between the metal and the surrounding environment. Surface plasmons display very important properties, including strongly enhanced local fields; tremendous sensitivity to changes in the local environment; and the ability to localize energy to tiny volumes not restricted by the wavelength of the exciting light.

Due to their unique properties, plasmons have found a broad range of applications in various areas of science. In chemistry and biology for example, the sensitivity of surface plasmons is used as the basis for powerful chemical and biochemical detectors that can monitor molecular binding events. In optics, the large field strengths of surface plasmons can dramatically enhance a variety of phenomena such as Raman scattering and light transmission through sub-wavelength apertures. In addition, the size of certain surface plasmonic configurations can be smaller than the wavelength of the exciting light, thus offering a path to scaling the sizes of optical components to below the diffraction limit.

Research number 0
.04

Grants

LABORATORY TEAM

金荣洪

教授

耿军平

副教授

梁仙灵

副教授

朱卫仁

特别研究员

RESEARCH PROJECTS

5. 国家自然科学基金面上项目 (项目编号:51777168)2018.01-2021.12,合作单位负责人
National Natural Science Foundation of China (No. 51777168), 2018.01-2021.12, 2nd PI
4. 国家自然科学基金青年项目 (项目编号:61701303)2018.01-2020.12,负责人
National Natural Science Foundation of China (No. 61701303), 2018.01-2020.12, PI
3. 上海市浦江人才计划 (项目编号:17PJ1404100),2017.07-2019.06,负责人
Shanghai Pujiang Program (No. 17PJ1404100), 2017.07-2019.06, PI
2. 上海市自然科学基金 (项目编号:17ZR1414300),2017.05-2020.04,负责人
Natural Science Foundation of Shanghai (No. 17ZR1414300), 2017.05-2020.04, PI
1. 上海交通大学特别研究员科研启动基金(项目编号:WF220403017),2016.04-2019.06,负责人
SJTU Inovation Research Grant (No. WF220403017), 2016.04-2019.06, PI

.05

PUBLICATIONS

PUBLICATIONS LIST
01 Jan 1970

期刊论文

Journal Publication

Journal Papers

期刊论文

Journal Papers
About The Publication

(2018)

 

[95] C. He, J. Chen, X. Liang, W. Zhu, J. Geng, and R. Jin, Direction finding by time modulated linear array, IEEE Transactions on Antennas and Propagation, (In press)

[94] H. Nawaz, X. Liang, M. S. Sadiq, J. Geng, W. Zhu, and R. Jin, Ruggedized planar monopole antenna with a null-filled shaped beam, IEEE Antennas and Wireless Propagation Letters, (In press)

[93] K. Wang, X. Liang, W. Zhu, J. Geng, J. Li, Z. Ding, and R. Jin, A dual-wideband dual-polarized aperture-shared patch antenna with high isolation, IEEE Antennas and Wireless Propagation Letters, (In press)

[92] Q. Chen, J. Gu, P. Liu,* J. Xie, J. Wang, Y. Liu, and W. Zhu,* Nanowire-based ultra-wideband absorber for visible and ultraviolet lightOptics and Laser Technology, 105, 102-105 (2018)

[91] J. Xie, W. Zhu,* I. D. Rukhlenko, F. Xiao, C. He, J. Geng, X. Liang, R. Jin, and M. Premaratne, Water metamaterial for ultra-broadband and wide-angle absorptionOptics Express26 (4), 5052-5059 (2018)

[90] W. Lv, F. Xie, Y. Huang, J. Li, X. Fang, A. Rashid, W. Zhu, I. D. Rukhlenko, and G. Wen, Nonlinear coupling states study of electromagnetic force actuated plasmonic nonlinear metamaterials, Optics Express26 (3), 3211-3220 (2018)

[89] J. Chen, X. Liang, C. He, H. Fan, W. Zhu, J. Geng, R. Jin, Instantaneous gain optimization in time modulated array using reconfigurable power divide/combiner, IEEE Antennas and Wireless Propagation Letters, (In press)

[88] H. Hapuarachchi, S. Mallawaarachchi, H. Hattori, W. Zhu, and M. Premaratne, Optoelectronic figure of merit of a metal nanoparticle – quantum dot (MNP-QD) hybrid molecule for assessing its suitability for sensing applications, Journal of Physics: Condensed Matter, 30, 054006 (2018)

[87] F. Xiao, W. Shang, W. Zhu, L. Han, M. Premaratne, T. Mei, and J. Zhao, Cylindrical vector beams excited tunable second harmonic generation in a plasmonic octamer, Photonics Research6 (3), 157-161 (2018)

[86] D. Wang, J. Geng, K. Wang, H. Zhou, G. Chenhu, X. Liang, W. Zhu, R. Jin, A high efficiency broadband omnidirectional UHF patch antenna applying surface plasmon polaritons for handheld terminals, IEEE Antennas and Wireless Propagation Letters17 (2), 283-286 (2018)

[85] 陈义峰, 梁仙灵, 李建平, 王堃, 贺冲,耿军平, 朱卫仁, 金荣洪, 一种紧凑型双圆极化有源接收天线设计, 电波科学学报,(已录用)

[84] 任杰, 张丽娜, 梁仙灵, 耿军平, 朱卫仁, 金荣洪, 一种低剖面宽带二维宽角扫描圆极化阵列天线,电波科学学报,(已录用)。

[83] 贡佩君, 耿军平, 梁仙灵, 朱卫仁, 金荣洪, 基于Rotman透镜天线的MAC协议设计,计算机工程与设计, vol.39 (1), 11-16, (2018).

 

(2017)

 

[82] M. Kang,* W. Zhu,*  and I. D. Rukhlenko, Experimental observation of topological structure of exceptional points in an ultrathin hybridized metamaterialPhysical Review A, 96, 063823 (2017)

[81] B. Liu, W. Zhu, S. D. Gunapala, M. I. Stockman, and M. Premaratne,  Open Resonator Electric Spaser, ACS Nano, 11(12), 12573-12582 (2017) (影响因子:13.942)

[80] H. Zhou, J. Geng, W. Zhu, J. Li, X. Liang,  and R. Jin, Wideband circularly polarized UHF crossed monopole antenna with unequal power feed for handheld terminals, IEEE Antennas and Wireless Propagation Letters, 16, 2915-2918 (2017)

[79] G. Chenhu, J. Geng, H. Zhou, J. Li, L. liu, X. Liang, W. Zhu, R. Jin, and R. W. Ziolkowski, Truncated circular cone, slot antenna array that radiates a circular polarized conical beam, IEEE Antennas and Wireless Propagation Letters, 16, 2574-2577 (2017)

[78] A. S. Baimuratov, T. P. Pereziabova, W. Zhu,* M. Y. Leonov, A. V. Baranov, A. V. Fedorov, and I. D. Rukhlenko,*  Optical anisotropy of topologically distorted semiconductor nanocrystals, Nano Letters, 17, 5514–5520 (2017) (影响因子:12.712)

[77] J. Chen, X. Liang, C. He, H. Fan, W. Zhu, R. Jin, and J. Geng, Efficiency improvement of time modulated array with reconfigurable power divider/combiner, IEEE Transactions on Antennas and Propagation, 65, 4027-4037 (2017)

[76] M. Kang, H. Wang, and W. Zhu, Wavefront manipulation with a dipolar metasurface under coherent control, Journal of Applied Physics, 122, 013105 (2017)

[75] M. Kang, W. Zhu, H. Wang, and M. Premaratne, Spawning a ring of exceptional points from a metamaterial, Optics Express, 25, 18265-18273 (2017)

[74] W. Zhu,* I. D. Rukhlenko, F. Xiao, C. He, J. Geng, X. Liang, M. Premaratne, and R. Jin, Multiband coherent perfect absorption in a water-based metasurface, Optics Express, 25, 15737-15745 (2017)

[73] F. Xiao, C. Liu, K. Liu, W. Shang, W. Zhu, and J. Zhao, Control the Raman response of individual carbon nanotubes by orbital angular momentum of light, Optics Letters, 42, 2491-2494 (2017)

[72] A. S. Baimuratov, A. I. Shlykov, W. Zhu, M. Y. Leonov, A. V. Baranov, A. V. Fedorov, and I. D. Rukhlenko, Excitons in gyrotropic quantum-dot supercrystals, Optics Letters, 42, 2423-2426 (2017)

[71] Z. Peng, X. Liang, W. Zhu, J. Geng, C. He, R. Jin, Y. Yao, and Y. Qian, Metal loaded sea-water antenna with high radiation efficiency and wideband characteristics, IEEE Antennas and Wireless Propagation Letters, 16, 1671-1674 (2017)

[70] Y. Yao, X. Liang, W. Zhu, J. Geng, and R. Jin, Phase mode analysis of radio beams carrying orbital angular momentum, IEEE Antennas and Wireless Propagation Letters16, 1127-1130 (2017)

[69] W. Shang, F. Xiao, W. Zhu, H. He, M. Premaratne, T. Mei, and J. Zhao, Fano resonance with high local field enhancement under azimuthally polarized excitation, Scientific Reports, 7, 1049 (2017)

[68] S. A. Andronaki, W. Zhu, M. Yu. Leonov, A. G. Shalkovskiy, A. V. Baranov, A. V. Fedorov, and I. D. Rukhlenko, Effect of extinction on separation of nanoparticle enantiomers with chiral optical forces, IEEE Photonics Journal, 9 (2), 4500906 (2017)

[67] I. A. Vovk, A. S. Baimuratov, W. Zhu, A. G. Shalkovskiy, A. V. Baranov, A. V. Fedorov, and I. D. Rukhlenko, Chiral nanoparticles in singular light fields, Scientific Reports, 7, 45925 (2017)

[66] W. Zhu,* F. Xiao, I. D. Rukhlenko, J. Geng, X. Liang, M. Premaratne, and R. Jin, Wideband visible-light absorption in an ultrathin silicon nanostructure, Optics Express, 25 (5), 5781 -5786 (2017)

[65]  袁林锋,梁仙灵,耿军平,朱卫仁,柳良,金荣洪, 一种适用于极化捷变天线的可重构射频网络设计电波科学学报32 (2), 170-175 (2017)

[64]  胡丹婷,耿军平,梁仙灵,朱卫仁,金荣洪,庄凯杰, 基于权值约束变换误差的虚拟阵列波束形成电波科学学报32 (1), 8-15 (2017)

 

(2016)

 

[63]  钱扬,耿军平,粱仙灵,朱卫仁,姚羽,彭政,金荣洪, “基于Bessel权向量的宽带波束形成器,” 电波科学学报31 (6), 1093-1098, 2016

[62] W. Zhu,* F. Xiao, M. Kang, D. Sikdar, X. Liang, J. Geng, M. Premaratne, R. Jin, MoS2 broadband coherent perfect absorber for terahertz wavesIEEE Photonics Journal8 (6), 5502207 (2016)

[61] F. Xiao,* W. Zhu,* W. Shang, M. Wang, P. Zhang, S. Liu, M. Premaratne, and J. Zhao, Optical Bloch oscillations and Zener tunneling of Airy beams in ionic-type photonic lattices, Optics Express24, 18332-18339 (2016).

[60] W. Zhu,* F. Xiao, M. Kang, and M. Premaratne, Coherent perfect absorption in an all-dielectric metasurfaceApplied Physics Letters, 108, 121901 (2016)

 

(2015)

 

[59] D. Sikdar, W. Zhu, W. Cheng, and M. Premaratne, Substrate-mediated broadband tunability in plasmonic resonances of metal nanoantennas on finite high-permittivity dielectric substratePlasmonics10,1663–1673 (2015).

[58] W. Zhu,* I. D. Rukhlenko, R. E. Noskov, R. Jin, and J. Zhou, Recent advances in theory and applications of electromagnetic metamaterials, International Journal of Antennas and Propagation2015, 982325, (2015).

[57]   H. Sun, Y. Huang, J. Li, W. Zhu, and G. Wen, Ultra-compact metamaterial absorber with low-permittivity dielectric substrateProgress In Electromagnetics Research M41, 25-32, 2015

[56] F. Xiao, W. Zhu, W. Shang, T. Mei, M. Premaratne, and J. Zhao, Electrical control of second harmonic generation in a graphene-based plasmonic Fano structure, Optics Express23, 3236-3244 (2015).

[55] S. Li,* Q. Zhang, W. Hu, W. Yu, X. Lv, and W. Zhu,* A uniplanar triple-band dipole antenna using complementary capacitively loaded loop, IEEE Antennas and Wireless Propagation Letters14, 743-746 (2015).

[54] W. Zhu,* D. Sikdar, F. Xiao, M. Kang, and M. Premaratne, Gold nanoparticles with gain-assisted coating for ultra-sensitive biomedical sensingPlasmonics10,881–886 (2015).

 

(2014)

 

[53] K. J. Si, Y. Chen, D. Sikdar, Z. Xu, H. Mu, Y. Tang, W. Xiong, P. Guo, S. Zhang, Y. Lu, Q. Bao, W. Zhu, M. Premaratne, and W. Cheng, Giant Plasmene Nanosheets, Nanoribbons and OrigamiACS Nano, 8, 11086-11093(2014). (影响因子:13.942)

[52]  M. Kang, Y. D. Chong, H. T. Wang, W. Zhu, and M. Premaratne, Critical route for coherent perfect absorption in a Fano resonant plasmonic systemApplied Physics Letters 105, 131103 (2014).

[51]  F. Xiao, B. Li, M. Wang, W. Zhu, P. Zhang, S. Liu, M. Premaratne, and J. Zhao, Optical Bloch oscillations of an Airy beam in a photonic lattice with a linear transverse index gradientOptics Express 22, 22763 (2014)

[50]  M. Kang, H. Cui, T. Li, J. Chen, W. Zhu, and M. Premaratne, Unidirectional phase singularity in ultrathin metamaterials at exceptional pointsPhysical Review A 89, 065801 (2014)

[49]  Y. Huang,* G. Wen, W. Zhu,* J. Li, L. Si, and M. Premaratne, Experimental demonstration of a magnetically tunable ferrite based metamaterial absorberOptics Express 22, 16408 (2014)

[48]  W. Zhu,* M. Premaratne, S. D. Gunapala, G. P. Agrawal, and M. I. Stockman, Quasi-Static analysis of controllable optical cross sections of a layered nanoparticle with a sandwiched gain layerJournal of Optics 16, 075003(2014) (Featured Article)

[47]  W. Zhu,* I. D. Rukhlenko, F. Xiao, and M. Premaratne, Polarization conversion in U-shaped chiral metamaterial with four-fold symmetry breakingJournal of Applied Physics 115, 143101 (2014)

[46]  M. Kang, H. T. Wang, and W. Zhu, Dual-band unidirectional circular polarizer with opposite handednesses filtration using hybridized metamaterialOptics Express 22, 9301 (2014)

[45]  Q. Zhang, L. Si,* Y. Huang, X. Lv, and W. Zhu,* Low-index-metamaterial for gain enhancement of planar terahertz antennaAIP Advances 4, 037103 (2014)

[44]  S. Zhu, L. Si, C. Guo, J. Shi, and W. Zhu, Hybrid PLL with Fast Locking Time and Low Spur in a 0.18 um CMOS ProcessChinese Physics B 23, 078401 (2014)

[43]  L. Si, Y. Liu, Y. Huang, and W. Zhu, Ka-band slot-microstrip-covered and waveguide-cavity-backed monopulse antenna arrayInternational Journal of Antennas and Propagation 2014, 707491 (2014)

[42]  W. Zhu,* F. Xiao, M. Kang, D. Sikdar, and M. Premaratne, Tunable terahertz left-handed metamaterial based on multi-layer graphene-dielectric compositeApplied Physics Letters 104, 051902 (2014)

[41]  F. Xiao, W. Zhu, M. Premaratne, and J. Zhao, Controlling Fano resonance of ring/ crescent-ring plasmonic nanostructure with Bessel beamOptics Express 22, 2132 (2014)

 

(2013)

 

[40] J. Li, F. Wang, G. Wen, Y. Huang, and W. Zhu, Planar metamaterial for matched waveguide terminationACES Journal 28, 1236-1243 (2013)

[39]  W. Zhu, L. Si, and M. Premaratne, Light focusing using epsilon-near-zero metamaterialsAIP Advances 3, 112124 (2013)

[38] I. D. Rukhlenko, V. Kalavally, W. Zhu, and M. Premaratne, Engineering optical nonlinearities in silicon-nanocrystal waveguidesJournal of the Optical Society of America B 12, 3145 (2013)

[37]  H. Sun, G. Wen, Y. Huang, J. Li, W. Zhu, and L. Si, Tunable band notch filters by manipulating couplings of SRRsApplied Optics 52, 7517-7522 (2013)

[36]  W. Zhu, I. D. Rukhlenko, Y. Huang, G. Wen, and M. Premaratne, Wideband giant optical activity and negligible circular dichroism of near-infrared chiral metamaterial based on a complimentary twisted configurationJournal of Optics 15, 125101 (2013)

[35]  W. Zhu, I. D. Rukhlenko, and M. Premaratne, Graphene metamaterial for optical reflection modulationApplied Physics Letters 102, 241914 (2013)

[34]  Y. Huang, Y. Tian, G. Wen, and W. Zhu, Experimentally study of absorption band controllable planar metamaterial absorber using asymmetrical snowflake shaped configurationJournal of Optics 15, 055104 (2013)

[33]  W. Zhu, I. D. Rukhlenko, L. Si, and M. Premaratne, Graphene-enabled tunability of optical fishnet metamaterialApplied Physics Letters 102, 121911 (2013)

[32]  K. Song, Y. Liu, Q. Fu, X. Zhao, C. Luo, and W. Zhu, 90º polarization rotator with rotation angle independent of substrate permittivity and incident angles using a composite chiral metamaterialOptics Express 21, 7439-7446 (2013)

[31]  L. Si, W. Zhu, and H. Sun, A compact, planar, and CPW-fed metamaterial-inspired dual-band antennaIEEE Antennas and Wireless Propagation Letters 12, 305-308 (2013)

[30]  L. Si, Y. Liu, H. Lu, H. Sun, X. Lv, and W. Zhu, Experimental realization of high transmittance THz 90˚-bend waveguide using EMXT structureIEEE Photonics Technology Letters 25 519-522 (2013)

[29]  W. Zhu, I. D. Rukhlenko, and M. Premaratne, Application of zero-index metamaterials for surface plasmon guidingApplied Physics Letters 102, 011910 (2013)

[28]  Y. Huang, G. Wen, J. Li, W. Zhu, P. Wang, and Y. Sun, Wide-angle and polarization-independent metamaterial absorber based on snowflake-shaped configurationJournal of Electromagnetic Waves and Applications 27, 552-559 (2013)

[27]  J. Zhong, F. Wang, G. Wen, Y. Huang, J. Li, W. Zhu, and H. Sun, Tunable triple-band negative permeability metamaterial consisting of single-loop resonators and ferriteJournal of Electromagnetic Waves and Applications 27, 267-275 (2013)

 

(2012)

 

[26]  W. Zhu, I. D. Rukhlenko, and M. Premaratne, Manipulating energy flow in variable-gap plasmonic waveguidesOptics Letters 37, 5151-5153(2012)

[25]  I. D. Rukhlenko, W. Zhu, M. Premaratne, and G. P. Agrawal, Effective third-order susceptibility of silicon-nanocrystal-doped silica, Optics Express 20, 26275-26284 (2012)

[24]  W. Zhu, M. Premaratne, and Y. Huang, Hiding inside an arbitrarily shaped metal pit using homogeneous metamaterialsJournal of Electromagnetic Waves and Applications 26, 2315-2322 (2012)

[23] W. Zhu, I. D. Rukhlenko, and M. Premaratne, Linear transformation optics for plasmonicsJournal of Optical Society of America B 29, 2659-2664 (2012)

[22]  K. Song, X. Zhao, Y. Liu, Q. Fu, and W. Zhu, Wide-angle 90˚-polarization rotator using chiral metamaterial with negative refractive indexJournal of Electromagnetic Waves and Applications 26, 1967-1976 (2012)

[21]  J. Zhong, Y. Huang, G. Wen, H. Sun, O. Gordon, and W. Zhu, Dual-band negative permittivity metamaterial based on cross circular loop resonator with shorting stubsIEEE Antennas and Wireless Propagation Letters 11, 803-806 (2012)

[20]  W. Zhu, I. D. Rukhlenko, and M. Premaratne, Light amplification in zero-index metamaterial with gain insertsApplied Physics Letters 101, 031907 (2012)

[19]  Y. Huang, G. Wen, J. Li, J. Zhong, P. Wang, Y. Sun, O. Gordon, and W. Zhu, Metamaterial absorbers realized in X-band rectangular waveguideChinese Physics B 21, 117801 (2012)

[18]  W. Zhu, I. D. Rukhlenko, and M. Premaratne, Maneuvering propagation of surface plasmon polaritons using complementary medium insertsIEEE Photonics Journal 4, 741-747 (2012)

[17]  W. Zhu, Y. Huang, I. D. Rukhlenko, G. Wen, and M. Premaratne, Configurable metamaterial absorber with pseudo wideband spectrumOptics Express 20, 6616-6621 (2012)

 

(2011)

 

[16]  C. Ding, X. Zhao, L. Hao, and W. Zhu, Acoustic metamaterial with split hollow spheresActa Physica Sinica 60, 044301 (2011)

[15]  J. Fan, G. Sun, and W. Zhu,* Electric and magnetic dipole couplings in split ring resonator metamaterialsChinese Physics B 20, 114101 (2011)

[14]  W. Zhu, I. Shadrivov, D. Powell, and Y. Kivshar, Hiding in the cornerOptics Express 19, 20827-20832 (2011)

[13]  郭晓静,赵晓鹏,刘亚红,朱卫仁, 基于零折射率超材料的高定向性微带天线电子技术应用 37 (6), 110-112 (2011)

[12]  W. Zhu, X. Zhao, and B. Gong, Left-handed metamaterials based on a leaf-shaped configurationJournal of Applied Physics 109, 093504 (2011)

[11]  W. Zhu, X. Zhao, B. Gong, L. Liu, and B. Su, Optical metamaterial absorber based on leaf-shaped cellsApplied Physics A 102, 147-151 (2011)

 

(2010 and before)

 

[10]  W. Zhu, C. Ding, and X. Zhao, A numerical method for designing acoustic cloak with homogeneous metamaterialsApplied Physics Letters 97, 131902 (2010)

[9]    W. Zhu, X. Zhao, S. Bao, and Y. Zhang, Highly symmetric planar metamaterial absorbers based on annular and circular patchesChinese Physics Letters 27, 014204 (2010)

[8]    W. Zhu, and X. Zhao, Metamaterial absorber with random dendritic cellsThe European Physical Journal Applied Physics 50, 21101 (2010)

[7]    W. Zhu, and X. Zhao, Adjusting the resonant frequency and loss of dendritic left-handed metamaterials with fractal dimensionJournal of Applied Physics 106, 093511 (2009)

[6]    W. Zhu, and X. Zhao, Metamaterial absorber with dendritic cells at infrared frequenciesJournal of Optical Society of America B 26, 2382-2385 (2009)

[5]    S. Tang, W. Zhu, and X. Zhao, Multiband negative index metamaterials at optical frequenciesActa Physica Sinica 58, 3223 (2009)

[4]    W. Zhu, and X. Zhao, Numerical study of low-loss cross left-handed metamaterials at visible frequencyChinese Physics Letters 26, 074212 (2009)

[3]    W. Zhu, X. Zhao, and J. Guo, Multibands of negative refractive indexes in the left-handed metamaterials with multiple dendritic structuresApplied Physics Letters 92, 241116 (2008)

[2]    B. Liu, X. Zhao, W. Zhu, W. Luo, and X. Cheng, Multiple pass-band optical left-handed metamaterials based on random dendritic cellsAdvanced Functional Materials 18, 3523-3528 (2008) (影响因子:12.12)

[1]    W. Zhu, X. Zhao, and N. Ji, Double bands of negative refractive index in the left-handed metamaterials with asymmetric defectsApplied Physics Letters 90, 011911 (2007)

01 Apr 2017

会议论文


Conference Papers 朱卫仁

会议论文

朱卫仁
Conference Papers
About The Publication

[33] J. Li, W. Zhu,* K. Wang, X. Bai, G. Chenhu, L. Liu, Y. Chen, X. Liang, J. Geng, and R. Jin,  Compact two-layer Rotman lens-fed circularly polarized antenna array, Asia-Pacific Conference on Antennas and Propagation, Xi’an China, Oct. 16-19, 2017.

[32] Y. Yao, X. Liang, W. Zhu, J. Geng, and R. Jin,  Synthesizing orbital angular momentum beam with small divergence angle, Asia-Pacific Conference on Antennas and Propagation, Xi’an China, Oct. 16-19, 2017.

[31] M. Zhu, X. Liang, Y. Yao, K. Zhuang, C. Ren, W. Zhu, J. Geng,  and R. Jin,  Realization of various OAM divergence angles based on Fabry-Perot antenna design, Asia-Pacific Conference on Antennas and Propagation, Xi’an China, Oct. 16-19, 2017.

[30] J. Ren, X. Liang, J. Geng,  W. Zhu, and R. Jin,  A wideband circularly-polarized crossed dipole antenna, Asia-Pacific Conference on Antennas and Propagation, Xi’an China, Oct. 16-19, 2017.

[29] R. Jin, J. Chen, C. He, X. Liang, W. Zhu, and J. Geng, Direction finding using time modulated array (Invited Talk), Asia-Pacific Conference on Antennas and Propagation, Xi’an China, Oct. 16-19, 2017.

[28] L. Shao, W. Zhu,* X. Liang, J. Geng, and R. Jin, Anomalous refraction in an all-dielectric gradient metasurface, Asia-Pacific Conference on Antennas and Propagation, Xi’an China, Oct. 16-19, 2017.

[27] Z. Mei, J. Geng, J. Li, G. Wei, R. Jin, X. Liang, W. Zhu, K. Wang, C. Wu, Co-share channel for wireless power and signal transmission in short range, IEEE 5th International Symposium on Electromagnetic Compatibility (EMC-Beijing), Beijing, China, 2017.

[26] S. Rehman, J. Geng, A. Rehman, R. Jin, X. Liang, W. Zhu, C. He, Active toroid nano antenna excited by a circular polarized plane wave, IEEE 5th International Symposium on Electromagnetic Compatibility (EMC-Beijing), Beijing, China, 2017.

[25] D. Wang, J. Geng, X. Liang, W. Zhu, C. He, A novel patch antenna based on surface plasma polarization, IEEE 5th International Symposium on Electromagnetic Compatibility (EMC-Beijing), Beijing, China, 2017.

[24] Y. Yao, X. Liang, W. Zhu, J. Li, J. Geng, R. Jin and K. Zhuang, Realizing orbital angular momentum (OAM) beam with small divergence angle by Luneberg lensIEEE Antennas and Propagation Symposium, San Diego, California, pp. 367-368, 9-14 July 2017.

[23] Y. Chen, X. Liang, W. Zhu, L. Liu, J. Geng, R. Jin, M. Zhu and G. Chenhu, A compact microtrip filtering power divider made of novel coupled resonators, IEEE Antennas and Propagation Symposium San Diego, California, pp. 2225-2226, 9-14 July 2017.

[22] W. Zhu,* C. He, X. Liang, J. Geng, and R. Jin, Coherent control of absorption in water based metamaterial, IEEE Antennas and Propagation Symposium, San Diego, California, pp. 1267-1268, 9-14 July 2017.

[21] L. Yuan, X. Liang, H. Fan, M. Zhu, W. Zhu, J. Geng, and R. Jin, A three-port reconfigurable network for multi-polarization antenna applications, IEEE Antennas and Propagation Symposium, San Diego, California, pp. 749-750, 9-14 July 2017.

[20] L. Liu, X. Liang, H. Zhou, Y. Chen, Y. Liang, R. Jin, J. Geng, W. Zhu, G. Chenhu, J. Li, Y. Yao, A single-pole-double-throw switch based on the ring structure, IEEE Antennas and Propagation Symposium, San Diego, California, pp. 2221-2222, 9-14 July 2017.

[19] K. Wang, X. Liang, W. Zhu, Z. Ding, Y. Yao, J. Li, J. Geng, and R. Jin, Broadband polarization reconfigurable microstrip antenna array, IEEE Antennas and Propagation Symposium, San Diego, California, pp. 2249-2250, 9-14 July 2017.

[18] J. Ren, L. Zhang, X. Liang, W. Yuan, Q. Qian, J. Geng, W. Zhu, and R. Jin, A wideband and wide-angle scanning circularly polarized array with low profile, IEEE Antennas and Propagation Symposium, San Diego, California, pp. 1815-1816, 9-14 July 2017.

[17] J. Ren, X. Liang, W. Yuan, J. Geng, W. Zhu, R. Jin, L. Zhang, and Q. Qian, Gain and sdelobe improved circularly-polarized array using HIS bowl-shaped reflector, IEEE Antennas and Propagation Symposium, San Diego, California, pp. 569-570, 9-14 July 2017.

[16] J. Li, W. Zhu,* H. Zhou, G. Chenhu, Y. Yao, J. Liu, X. Liang, J. Geng, and R. Jin, Minimizing gain roll-off in Rotman lens antenna using phase gradient transmission lines, IEEE Antennas and Propagation Symposium, San Diego, California, pp. 2097-2098, 9-14 July 2017.

[15] G. Chenhu, J. Geng, H. Zhou, J. Li, Y. Chen, W. Zhu, X. Liang, R. Jin, and R. Ziolkowski, A T-shaped feed structure to enhance the performance of a polarization diversity antenna, IEEE Antennas and Propagation Symposium, San Diego, California, pp. 2143-2144, 9-14 July 2017.

[14] G. Chenhu, J. Geng, L. Liu, H. Zhou, X. Zhao, Y. Liang, X. Liang, W. Zhu, R. Jin, and R. Ziolkowski, A circular truncated cone slot antenna with circular polarized conical beam, IEEE Antennas and Propagation Symposium, San Diego, California, pp. 1533-1534, 9-14 July 2017.

[13] D. Wang, J. Geng, R. Jin, X. Liang, W. Zhu, X. Wang, C. Ren, and R. Ziolkowski, A surface plasmon polariton inspired patch antenna, IEEE Antennas and Propagation Symposium, San Diego, California, pp. 2499-2500, 9-14 July 2017.

[12] D. Wang, J. Geng, R. Jin, X. Liang, W. Zhu, L. Liu, H. Qi, and Y. Xu, A single-fed circularly polarized using water substrate patch antenna with small size low-profile and broadband, IEEE Antennas and Propagation Symposium, San Diego, California, pp. 1211-1212, 9-14 July 2017.

[11] C. He, X. Liang, W. Zhu, J. Geng, R. Jin, A. Cao, and H. Di, Direction finding by time modulated linear array, IEEE Antennas and Propagation Symposium, San Diego, California, pp. 315-316, 9-14 July 2017.

[10]  H. Zhou, J. Geng, R. Jin, X. Liang, W. Zhu and L. Liu, A novel low-profile circularly polarized UHF crossed dipole antenna (Invited talk), International Workshop on Antenna Technology (iWAT2017), March 1-3, Athens, Greece, (2017)

[9]  D. Sikdar, K. J. Si, W. Zhu, W. Cheng, and M. Premaratne, Plasmene: An artificial graphene from plasmonic nanoparticle family, CLEO/Europe-EQEC Conference, Munich, Germany, (2015)

[8]  C. Rupasinghe, W. Zhu, and M. Premaratne, Spaser powered photothermal cancer therapy using graphene and carbon nanotubesIEEE Photonics Society Annual Meeting (Oct. 12-16, 2014, San Diego, California, USA), pages 16-17, (2014)

[7] H. Sun, G. Wen, Y. Huang, J. Zhong, and W. Zhu, Tunable ferrite based triple-band mu-negative metamaterialAsia Communications and Photonics Conference (Nov. 7-10, 2012, Guangzhou, China),  paper ATh4G.4.

[6] H. Sun, G. Wen, Y. Huang, J. Zhong, and W. Zhu, Dual-band metamaterial absorber based on asymmetrical snowflake-shaped resonatorsAsia Communications and Photonics Conference (Nov. 7-10, 2012, Guangzhou, China), paper AS1B.6

[5] L. Si, W. Zhu, and X. Lv, Determination of the effective constitutive parameters of active transmission line metamaterialsInternational Workshop on Metamaterials (Oct. 8-10, 2012, Nanjing, China), paper 120002.

[4] Y. Huang, G. Wen, and W. Zhu, Tunable metamaterials based on ferrites and the applicationsInternational Workshop on Metamaterials (Oct. 8-10, 2012, Nanjing, China), 120047 (2012).

[3] J. Fan, D. Li, and W. Zhu, Transmission line characteristics based on metamaterials substrate, Advanced Materials Research, 415-417, 302-305 (2012)

[2] J. Zhong, Y. Huang, G. Wen, H. Sun, and W. Zhu, The design and applications of tunable metamaterials, International Workshop on Information and Electronics Engineering, 29, 802-807 (2012)

[1] J. Zhong, Y. Huang, G. Wen, H. Sun, and W. Zhu, Tunable dual-band negative refractive index metamaterial consisting of ferrites and SRR-wires, International Workshop on Information and Electronics Engineering, 29, 797-801 (2012)

01 Jan 1970

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.06

Honors and Awards

Awards

2018

IEEE Senior Member

IEEE高级会员

2017

Shanghai Pujiang talent program by Shanghai Science and technology commission

上海浦江人才计划

2012

Best Doctoral Thesis Award by Northwestern Polytechnical University

西北工业大学优秀博士学位论文

2010

Innovation Research Award by Applied Materials Inc. US

应用材料创新基金

2010

Baosteel Education Award granted by Baosteel Inc. China

宝钢优秀研究生奖学金
.07

Academic Services

  • IEEE Photonics Journal (SCI收录,Impact Factor 2.291), Associate Editor 副编辑
  • Journal of Physics: Condensed Matter (SCI收录,Impact Factor 2.649), Guest Editor 客座编辑 [Open for submission]
  • International Journal of Antennas and Propagation (SCI收录,Impact Factor 1.164), Lead Guest Editor 客座主编
  • Frontiers of Physics (Web of Science ESCI收录), Editorial Board Member 编委
  • Senior Member, The Institute of Electrical and Electronics Engineers (IEEE)
  • Member, The Optical Society of America (OSA)
  • Member, The International Society for Optics and Photonics (SPIE)
  • Service as a reviewer for over 20 Journals, including Applied Physics Letters, Optics Letters, Optics Express, ACS Nano, Nano Letters, Scientific Reports, and IEEE journals
  • Session Chair, “Metasurfaces for Novel Electromagnetic Wavefront Manipulation” in 2018 IEEE 7th Asia-Pacific Conference on Antennas and Propagation, Auckland, New Zealand, 5-8 August, 2018 [Open for submission]
  • TPC Member, 2018 IEEE 7th Asia-Pacific Conference on Antennas and Propagation, Auckland, New Zealand, 5-8 August, 2018
.08

Teaching and Students

开设课程 Teaching
  • XXXX
    XXXX
    教学楼

    超材料技术及多模传感器

    电子信息与电气工程学院

    每年春季为本科生开设课程: 32学时
培养学生

Opening

We are seeking for highly motivated new colleagues at all levels: PhD students, master students, undergraduates, and postdoctoral fellows with solid scientific strength and strong interest in one of the following areas: electromagnetic metamaterials, antennas and RF devices, wireless network, and sensors. If you are currently studying or would like to study/work at SJTU with me (or just want to have a discussion with your brilliant idea), please feel free to send me an email to arrange an appointment.

在读学生/Current Students

I am fortunate to work with the following excellent students:

李建平/Mr Jianping Li (PhD student, 2015 - present, co-supervised with Prof. Ronghong Jin) 

邵琳达/Ms Linda Shao (PhD student, 2017 - present)

Mr Muhammad Rizwan Akram (PhD student, 2017 - present)

谢剑文/Mr Jianwen Xie (MS student, 2017 - present) 

蔡奎/Mr Kui Cai (MS student, 2017 - present)

高源/Mr Yuan Gao (Undergraduate student, 2017 - present)

已毕业学生/Alumni

Wish them all the best for their future endeavors:

Dr. Chanaka Rupasinghe (PhD, co-supervised with Prof. Malin Premaratne at Monash University, Australia)

Dr. Debabrata Sikdar (PhD, co-supervised with Prof. Malin Premaratne at Monash University, Australia)