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成果及论文

特邀综述论文(Invited Review)


[8] L. Shao and W. Zhu,* Graphene‐derived microwave metamaterials and meta‐devices: Emerging applications and properties, Electron, 2, e60 (2024).

[7] F. Faraz, J. Tian, T. U. R. Abbasi, and W. Zhu,* Recent Advances in Geometric Phase Metasurfaces: Principles and Applications, Advanced Physics Research, 3, 343001 (2024).

[6] L. Shao and W. Zhu,* Recent advances in electromagnetic metamaterials and metasurfaces for polarization manipulation, Journal of Physics D: Applied Physics, 57, 343001 (2024).

[5] D. Liu, L. Hao*, W. Zhu*, X. Yang, X. Yan, C. Guan, Y. Xie, S. Pang, and Z. Chen, Recent progress in resonant acoustic metasurfaces, Materials, 16, 7044 (2023).

[4] Z. Li, I. D. Rukhlenko, and W. Zhu,* Recent advances in microwave metasurface holography and its data encryption applications,  Journal of Optics, 24, 113001 (2022) .

[3] L. Shao, I. D. Rukhlenko, and W. Zhu,* Electrically Reconfigurable Microwave Metasurfaces, Chinese Optics Letters, 20(10), 103601 (2022). 

[2] J. Zhang and W. Zhu,* Graphene-based microwave metasurfaces and Radio-Frequency devices,  Advanced Photonics Research, 2, 2100142 (2021). 

[1] L. Shao, and W. Zhu,* Electrically reconfigurable microwave metasurfaces with active lumped elements: A mini review, Frontiers in Materials, 8, 689665 (2021). 



-2024 


[204] N. Mu,# C. Zhang,# C. Yang, K. Ma, Y. Lai, Y. Chen, P. Chen, H. Yang, Y. Zhao, F. Li, X. Bian,* W. Zhu,* H. Feng,* T. Chen,* Terahertz meta-biosensor for subtype detection and chemotherapy monitoring of glioma cellsMaterials & Design, 243, 113294 (2024).

[203] A. Cao, N. Chen, W. Zhu,* and Z. Chen,* Graphene-Based Dual-Band Metasurface Absorber with High Frequency Ratio, Nanomaterials 14, 1522 (2024).

[202] Y. Huang, Z. Zhang, C. He, X. Wang, and W. Zhu,* Chirality‐Assisted Spin‐Decoupled Metasurface Implemented by Simple Geometrical Rotation, Advanced Materials Technologies 9, 2401145 (2024).

[201] L. Shao and W. Zhu,* Graphene‐derived microwave metamaterials and meta‐devices: Emerging applications and properties, Electron, 2, e60 (2024).

[200] J. Zhang, P. Liu, Z. Xu, Y. Dai, Q. Zhang, W. Zhu, E. I. Kauppinen, and Z. Sun,* Hyperband Synergistic Metadevices, Advanced Optical Materials, 12, 2401187 (2024).

[199] F. Faraz, J. Tian, T. U. R. Abbasi, and W. Zhu,* Recent Advances in Geometric Phase Metasurfaces: Principles and Applications, Advanced Physics Research, 3, 343001 (2024).

[198] F. Faraz, Y. Huang,   Z. Zhang, X. Wu, G. Chu, T. Ur. R. Abbasiand, X. Wang, L. Si,* and  W. Zhu,* Multi-fold geometric phase metasurface with versatile operations for transmission and reflectionMaterials & Design, 243, 113090 (2024).

[197] L. Shao and W. Zhu,* Recent advances in electromagnetic metamaterials and metasurfaces for polarization manipulation, Journal of Physics D: Applied Physics, 57, 343001 (2024).

[196] L. Si,* K. Han, X. Bao, H. Sun, and W. Zhu,* Miniaturized bandpass metamaterials filters using hybrid plasmonic waveguide and defected surface structuresInternational Journal of Electronics and Communications 179, 155336 (2024).

[195] L. Si,* K. Han, R. Niu, L. Dong, W. Xing, W. Zhu,* Miniaturized leaky-wave antenna with backward-to-forward beam scanning and suppressed open stop-band based on substrate-integrated plasmonic waveguide, Optics Express 32 (11), 19352-19360 (2024).

[194] H. Shi, J. Tian, N. Chen, W. Zhu,* Wideband high-efficiency scattering reduction in a graphene based optically transparent and flexible metasurface, Carbon, 225, 119150 (2024).

[193] L. Si,* R. Niu, G. Cheng, W Zhu,* Experimental realization of a transmissive microwave metasurface for dual vector vortex beams generation, Optics Express 32 (8), 14892-14903 (2024).

[192] Q. Li, J. Zhang, L. Liu, C. He, W. Zhu,* Graphene-based optically transparent metasurface for microwave and terahertz cross-band stealth utilizing multiple stealth strategies, Carbon, 217, 118599 (2024).

[191] F. Faraz, Z. Zhang, Y. Huang, H. Fraz, T. Ur. Abbasi, X. Wang, and W. Zhu,* Bi‐Layer Reflection‐Transmission Dual‐Mode Metasurface with Flexible Bandwidth Control, Advanced Optical Materials2302608 (2024).

[190] J. Tian, H. Shi, S. Li, C. He, W. Zhu,* Single-Layer Programmable Metasurface for Manipulating Both Linearly and Circularly Polarized Electromagnetic Waves, ACS Applied Optical Materials, 2, 341-349 (2024).

[189] Z. Li, Z. Zhang, X. Wu, K. Song,* S. Zhai, Y. Liu, J. Lou,* X. Wang, X. Zhao, W Zhu,* Chiral Meta-Coder for Spin Switchable Electromagnetic Camouflage and Information AuthenticationLaser & Photonics Reviews, 2301084 (2024).

[188] L. Shao, Z. Zhang, X. Wang, C. He, L. Si, I. D. Rukhlenko, and W. Zhu,* Graphene-based ultralow-profile microwave Fresnel lens, Carbon, 217, 118599 (2024).


-2023 

[187] X. Wu, Z. Li, Z. Zhang, X. Wang, L. Si, and W. Zhu,* Mechanically Reconfigurable Folded Reflectarray Antenna for Variable Near-Field Focusing, IEEE Transactions on Antennas and Propagation, 71,10038-10043 (2023).

[186] D. Liu, L. Hao*, W. Zhu*, X. Yang, X. Yan, C. Guan, Y. Xie, S. Pang, and Z. Chen, Recent Progress in Resonant Acoustic Metasurfaces (Review), Materials, 16, 7044 (2023).

[185] F. Faraz, Y. Huang, H. Liu, T. Ur R. Abbasi, X. Wang, L. Si,* W. Zhu,* High-Efficiency Dual-Band Metasurface with Independent Multifold Geometric Phases, Advanced Optical Materials, 11, 2300347 (2023).

[184] Q. Li, J. Zhang, I. D. Rukhlenko, and W. Zhu,* Graphene-enabled metasurface with independent amplitude and frequency controls in orthogonal polarization channels, Carbon, 206, 260-267 (2023).

[183] Z. Li, J. Zhang, J. Liu, L. Liu, X. Wang, M. Premaratne, J. Yao, and W. Zhu,* Independent Manipulation of Aperture and Radiation Fields in a Transmission-Reflection Integrated Complex-Amplitude Metasurface, Advanced Materials Technologies, 8, 2201192 (2023).

[182] N. Chen, C. He, and W. Zhu,* Lightweight Machine-Learning Model for Efficient Design of Graphene-Based Microwave Metasurfaces for Versatile Absorption Performance, Nanomaterials, 13, 329 (2023).

[181] M. Sun, J. Qian, X. Bai,* L. Zhou, Y. Lv, F. Kong, W. Zhu* and R. Jin,  Compact Hybrid Choke Rings for Dual-Band Circularly Polarized GPS Antenna, IEEE Antennas and Wireless Propagation Letters,  22(1), 9-13 (2023).

[180] L. Shao, Z. Li, J. Feng, J. Zhang, H. Shi, X. Bai,* and W. Zhu,* Transmissive metasurface for multi-channel and full-polarization modulation of electromagnetic wavefronts, Photonics Research, 11(2), 245-251 (2023).

[179] F. Faraz, Z. Li, Z. Zhang, T. Ur R. Abbasi, X. Wang, I. D. Rukhlenko, and W. Zhu,* High-Efficiency Geometric Phase Metasurface with Multifold Rotationally Symmetric Resonators, ACS Applied Optical Materials, 1, 173−178 (2023).


-2022

[178] X. Wu and W. Zhu,* Modified Metasurface Alvarez Lens Based on Phase Compensation in Microwave Band, Optics Express, 30, 25400-25409 (2022).

[177] X. Bai, F. Zhang,* L. Sun, A. Cao, J. Zhang, C. He,* L. Liu, J. Yao, and W. Zhu,* Time-Modulated Transmissive Programmable Metasurface for Low Side-Lobe Beam Scanning, Research, 2022, 9825903 (2022).

[176] C. Zhang, T. Xue, J. Zhang, Z. Li, L. Liu, J. Xie, J. Yao, G. Wang,* X. Ye,* and W. Zhu,* Terahertz Meta-biosensor based on High-Q Electrical Resonance Enhanced by the Interference of Toroidal Dipole, Biosensors and Bioelectronics, 214, 114493 (2022).

[175] J. Zhang, L. Shao, Z. Li, C. Zhang, and W. Zhu,* Graphene-based Optically Transparent Metasurface Capable of Dual-Polarized Modulation for Electromagnetic Stealth, ACS Applied Materials & Interfaces, 14, 31075–31084 (2022).

[174] J. Zhang, Z. Li, C. Zhang, L. Shao, and W. Zhu,* Graphene Based Metasurface for Dynamic Manipulation of Microwave Polarization, npj 2D Materials and Applications, 6, 47 (2022).

[173] L. Shao, I. D. Rukhlenko, and W. Zhu,* Electrically Reconfigurable Microwave Metasurfaces, Chinese Optics Letters, 20(10), 103601 (2022). (Invited Review)

[172] L. Shao, Z. Li, Z. Zhang, X. Wang, and W. Zhu,* Multi-Channel Metasurface for Versatile Wavefront and Polarization Manipulation,  Advanced Materials Technologies,  7, 2200524(2022).

[171] Z. Li, I. D. Rukhlenko, and W. Zhu,* Recent advances in microwave metasurface holography and its data encryption applications,  Journal of Optics, 24, 113001 (2022) . (Invited Review)

[170] Z. Li,  X. Kong, J. Zhang, L. Shao, D. Zhang, J. Liu, X. Wang, W. Zhu,* and C.-W. Qiu,* Cryptography metasurface for one-time-pad encryption and massive data storage,  Laser & Photonics Reviews, 16, 2200113 (2022).

[169] L. Hao, Y. Li, X. Yan, X. Yang, X. Guo, Y. Xie, S. Pang, Z. Chen,* and W. Zhu,* Tri-band negative modulus acoustic metamaterial with nested split hollow spheres, Frontiers in Materials, 9, 909671 (2022).

[168] Z. Li,  J. Qi, W. Hu, J. Liu,  J. Zhang, L. Shao, C. Zhang, X. Wang, R. Jin, and W. Zhu,* Dispersion-assisted dual-phase hybrid meta-mirror for dual-band independent amplitude and phase controls, IEEE Transactions on Antennas and Propagation, 70, 7316-7321 (2022).

[167] Z. Li,  J. Liu,  J. Zhang, L. Shao, C. Zhang, X. Wang, R. Jin, and W. Zhu,* Shaping electromagnetic fields with irregular metasurface,  Advanced Materials Technologies, 7, 2200035 (2022).

[166] X. Bai, F. Zhang,* L. Sun, A. Cao, C. He, J. Zhang, and W. Zhu,*  Dynamic Millimeter-Wave OAM Beam Generation Through Programmable Metasurface, Nanophotonics, 11, 1389–1399 (2022).

[165] X. Song, X. Bai,* and W. Zhu,*   Reconfigurable metasurface for nearly full-range and continuous modulation of reflection, transmission, and absorption, ACS Applied Electronic Materials, 4, 1225−1231 (2022).

[164] L. Shao, D. Zhang, J. Liu, J. Zhang, Z. Li, X. Wang, and W. Zhu,*   Single-layer Non-interleaved Metasurface for Arbitrary Vector Beam Conversion in Triple Bands, ACS Applied Electronic Materials, 4, 443–451 (2022)

[163] C. Zhang, T. Xue, J. Zhang, L. Liu, J. Xie, G. Wang, J. Yao, W. Zhu,* and X. Ye*,  Terahertz toroidal metasurface biosensor for sensitive distinction of lung cancer cells, Nanophotonics, 11, 101-109 (2022).

[162] Z. Li, D. Zhang, J. Liu,  J. Zhang, L. Shao, X. Wang, R. Jin, and W. Zhu,* 3-D manipulation of dual-helical electromagnetic wavefronts with a non-interleaved metasurface,  IEEE Transactions on Antennas and Propagation, 70, 378-388 (2022).


-2021

[161] C. Zhang, X. Zhang, P. Xie, H. Hou, K. Liu, J. Lou, H. Bao, J. Zhang, Z. Li, W. Zhu,* and G. Wang*,  Filter-assisted metasurface for full-space wavefront manipulation and energy allocation, ACS Applied Electronic Materials, 3, 4465–4471 (2021).

[160] X. Song, W. Yang, K. Qiu, X. Bai, K. Chen, Y. Feng, and W. Zhu,* Switchable metasurface for nearly perfect reflection, transmission, and absorption using PIN diodes, Optics Express, 29(18), 29320-29328 (2021).

[159] J. Zhang, Z. Li, L. Shao, F. Xiao, and W. Zhu,* Active modulation of electromagnetically induced transparency analog in graphene-based microwave metamaterial, Carbon, 183, 850-857 (2021).

[158] J. Zhang and W. Zhu,* Graphene-based microwave metasurfaces and Radio-Frequency devices,  Advanced Photonics Research, 2, 2100142 (2021). (Invited Review)

[157] Z. Li, D. Zhang, J. Liu,  J. Zhang, L. Shao, X. Wang, R. Jin, and W. Zhu,* Polarization-assisted visual secret sharing encryption in metasurface hologram,  Advanced Photonics Research, 2, 2100175 (2021).

[156] F. Xiao, W. Zhu,* X. Wei, and I. D. Rukhlenko, Editorial: Theory and Applications of Electromagnetic Metamaterials, Frontiers in Physics, 9, 717484 (2021).

[155] L. Shao, and W. Zhu,* Electrically reconfigurable microwave metasurfaces with active lumped elements: A mini review, Frontiers in Materials, 8, 689665 (2021). (Invited Review)

[154] J. Zhang#, N. Mu#, L. Liu, J. Xie, H. Feng, J. Yao, T. Chen,* and W. Zhu,* Highly sensitive detection of malignant glioma cells using metamaterial-inspired THz biosensor based on electromagnetically induced transparencye, Biosensors and Bioelectronics, 185, 113241 (2021).

[153] J. Zhang, Z. Li, L. Shao, and W. Zhu,* Dynamical absorption manipulation in a graphene-based optically transparent and flexible metasurface, Carbon, 176, 374-382 (2021).

[152] C. Ren, J. Geng, H. Zhou, K. Wang, X. Liang, W. Zhu, R. Jin, An approach to achieve directional low‐profile antenna of quintuple stable pattern band by utilising dipole with compound concave corrugated reflector, IET Microwaves, Antennas & Propagation, accepted.

[151] H. S. Khaliq, M. R. Akram, K. Riaz, M. A. Ansari, J. Akbar, J. Zhang, W. Zhu, D. Zhang, X. Wang, M. Zubair, and M. Q. Mehmood, Single-layered meta-reflectarray for polarization retention and spin-encrypted phase-encoding, Optics Express, 29(3), 3230-3242 (2021).


-2020

[150] S. Quader, M. R. Akram, F. Xiao, and W. Zhu,* Graphene based ultra-broadband terahertz metamaterial absorber with dual-band tunability, Journal of  Optics, 22, 095104 (2020).

[149] J. Zhang, H. Zhang, W. Yang, K. Chen, X. Wei, Y. Feng, R. Jin, and W. Zhu,* Dynamic scattering steering with graphene-based coding meta-mirror, Advanced Optical Materials, 8, 2000683 (2020).

[148] Q. Peng, M. R. Akram, I. D. Rukhlenko, and W. Zhu,* Highly transmissive bilayer Huygens’ metasurface with over 315◦ phase coverage, International Journal of Electronics and Communications, 124(8), 153330 (2020).

[147] Z. Li, M. Premaratne, and W. Zhu,* Advanced encryption method realized by secret shared phase encoding scheme using a multi-wavelength metasurfacee, Nanophotonics, 9, 3687–3696 (2020).

[146] X. Bai,* F. Kong, Y. Sun, F. Wang, J. Qian, X. Li,* A. Cao, C. He,* X. Liang, R. Jin, and W. Zhu,* High-efficiency transmissive programable metasurface for multi-mode OAM generations, Advanced Optical Materials, 8, 2000570 (2020).

[145] M. R. Akram, C. He, and W. Zhu,* Bi-layer metasurface based on Huygens’ principle for high gain antenna applications, Optics Express, 28(11), 15844-15854 (2020).

[144] Y. Yu, F. Xiao, C. He, R. Jin, and W. Zhu,* Double-arrow metasurface for dual-band and dual-mode polarization conversion, Optics Express, 28(8), 11797-11805 (2020).

[143] Y. Yu, F. Xiao, I. D. Rukhlenko, and W. Zhu,* High-efficiency ultra-thin polarization converter based on planar anisotropic transmissive metasurface, International Journal of Electronics and Communications, 118(8), 153141 (2020).

[142] S. Quader, J. Zhang, M. R. Akram, and W. Zhu,* Graphene-based high-efficiency broadband tunable linear-to-circular polarization converter for terahertz waves, IEEE Journal of Selected Topics in Quantum Electronics, 26(5), 4501008 (2020).

[141] M. R. Akram, G. Ding, K. Chen, Y. Feng, and W. Zhu,* Ultra-thin single layer metasurfaces with ultra-wideband operation for both transmission and reflection, Advanced Materials, 32, 1907308 (2020).

[140] J. Zhang, X. Wei, I. D. Rukhlenko, H.-T. Chen, and W. Zhu,* Electrically tunable metasurface with independent frequency and amplitude modulations, ACS Photonics, 7(1) , 265-‌271 (2020)

[139] J. Zhang, F. Lu, W. Zhang, W. Yu,  W. Zhu, M. Premaratne, T. Mei, F. Xiao, and J. Zhao, Nanometric optical trapping using plasmon gap mode of silver-coated fiber tip on gold film,  Journal of Physics: Condensed Matter, accepted.

[138] L. Wang, J. Geng, K. Wang, H. Zhou, C. Ren, H. Wu, X. Zhao, C. He, X. Liang, W. Zhu, and  R. Jin, Wideband Dual-Polarized Binary Coding Antenna with Wide Beamwidth and Its Array for Millimeter-Wave Applications,  IEEE Antennas and Wireless Propagation Letters, 19(4), 636-640 (2020).

[137] H. Wu, J. Geng, K. Wang, H. Zhou, X. Zhao, C. He, X. Liang, W. Zhu, and  R. Jin, A Low-profile Wideband Dual-polarized Antenna Based on an Improved HIS and Its Broad-angle Beam-Scanning Array,  IEEE Antennas and Wireless Propagation Letters, 19(3), 383-387 (2020).

[136] F. Xiao, J. Zhang, W. Yu, W. Zhu, T. Mei, M. Premaratne, and J. Zhao, Reversals of optical binding force in a plasmonic hetero-dimmer enabled by a radially polarized illumination,  Optics Express, 28(3), 3000-3008 (2020).

[135] Y. Liu, C. He, X. Liang, W. Zhu, J. Geng, and  and  R. Jin, Multi-user Communication by Electromagnetic Vortex Based on Time Modulated Array,  IEEE Antennas and Wireless Propagation Letters, 68(1), 509-520 (2020).

[134] J. Chen, C. He, X. Liang,  L. Bai, X. Bai, and W. Zhu, and  R. Jin, Direction finding of linear frequency modulation signal in time modulated array with pulse compression,  IEEE Transactions on Antennas and Propagation, 19(2), 282-286 (2020).


-2019

[133] K. Cai, C. He, F. Xiao, I. D. Rukhlenko, and W. Zhu,* Resonant mode coupling in hybrid all-dielectric metamaterial, Materials Research Express, 6, 125801 (2019).

[132] X. Bai,* F. Kong, J. Qiao, Y. Song, C. He, X. Liang, R. Jin, and W. Zhu,* Polarziation-insensitive metasurface lens for efficient generation of convergent OAM beams, IEEE Antennas and Wireless Propagation Letters, 18 (3), 2696-2700 (2019).

[131] N. V. Tepliakov,* E. V. Kundelev, P. D. Khavlyuk, Y. Xiong, M. Yu. Leonov, W. Zhu,* A. V. Baranov, A. V. Fedorov, A. L. Rogach, and I. D. Rukhlenko,* Sp2-Sp3-hybridized atomic domains determine optical features of carbon dots,  ACS Nano,13(9) , 10737-‌10744 (2019).

[130] X. Bai,* A. Cao, F. Kong, J. Qian, S. Xu, W. Yan, C. He, X. Liang, R. Jin, and  W. Zhu,* Rotman lens-fed Fabry-Perot resonator antennas for generating converged multi-mode OAM beams, IEEE Access, 7, 105768-‌105775 (2019).

[129] J. Zhang, X. Wei, M. Premaratne, and W. Zhu,* Experimental demonstration of electrically tunable broadband coherent perfect absorber based on graphene-electrolyte-graphene sandwich structure, Photonics Research, 7(8) , 868-874 (2019).

[128] D. Sikdar* and W. Zhu,* Editorial: A Special Issue on Plasmonic Metamaterials, Journal of Physics: Condensed Matter, 31 , 310401 (2019).

[127] R. Zhao, B. Gong, F. Xiao, C. He, and W. Zhu,* Circuit model analysis of switchable perfect absorption/reflection in an active frequency selective surface, IEEE Access, 7 , 55518-55523 (2019).

[126] L. Shao, W. Zhu,* M. Y. Leonov, and I. D. Rukhlenko, Dielectric 2-bit coding metasurface for electromagnetic wave manipulation, Journal of Applied Physics, 125, 203101 (2019). (Selected as Cover Article)

[125] L. Shao, M. Premaratne, and W. Zhu,* Dual-functional coding metasurfaces made of anisotropic all-dielectric resonators, IEEE Access, 7 , 45716-45722 (2019).

[124] M. R. Akram, M. Q. Mehmood, X. Bai, R. Jin, M. Premaratne, and W. Zhu,* High efficiency ultrathin transmissive metasurfaces, Advanced Optical Materials, 7, 1801628 (2019).

[123] M. R. Akram, X. Bai, R. Jin, G. A. E. Vandenbosch, M. Premaratne, and W. Zhu,* Photon spin Hall effect based ultra-thin transmissive metasurface for efficient generation of OAM waves,  IEEE Transactions on Antennas and Propagation, 67 (7), 4650-4658 (2019).

[122] M. R. Akram, M. Q. Mehmood, T. Tauqeer, A. S. Rana, I. D. Rukhlenko, and W. Zhu,* Highly efficient generation of Bessel beams with polarization insensitive metasurfaces, Optics Express, 27(7) , 9467-9480 (2019).

[121] J. Xie, S. Quader, F. Xiao, C. He, X. Liang, J. Geng, R. Jin, W. Zhu,* and I. D. Rukhlenko, Truly all-dielectric ultra-broadband metamaterial absorber: Water-based and ground-free, IEEE Antennas and Wireless Propagation Letters, 18 (3), 536-540 (2019).

[120] J. Li, R. Jin, J. Geng, X. Liang, K. Wang, M. Premaratne, and W. Zhu,* Design of a broadband metasurface Luneburg lens for full-angle operation, IEEE Transactions on Antennas and Propagation, 67 (4), 2442-2451 (2019).

[119] W. Shang,  F. Xiao, W. Zhu, L. Han, T. Mei, and J. Zhao, Characterizing localized surface plasmon resonances using focused radially polarized beam, Applied Optics, 58(21), 5812-5816 (2019).

[118] F. Xiao, S. Cao, W. Shang,  W. Zhu, L. Han, T. Mei, M. Premaratne, and J. Zhao, Enhanced second harmonic generation assisted by breathing mode in multiresonant plasmonic trimer, Optics Letters, 44(15), 3813-3816 (2019).

[117] L. Liu, R. Jin, X. Liang, H. Fan, X. Bai, H. Zhou, J. Geng, W. Zhu, A Generalized approach for multifrequency transmission line transformer with frequency-dependent complex source and load, IEEE Transactions on Microwave Theory and Techniques, 67 (9), 3603-3616 (2019).

[116] Z. Ding, R. Jin, J. Geng, W. Zhu, X. Liang, Varactor loaded pattern reconfigurable patch antenna with shorting pins, IEEE Transactions on Antennas and Propagation, 67 (10), 6267-6277 (2019).

[115] Y. Yao, X. Liang, W. Zhu, J. Geng, and R. Jin, Experiments of orbital angular momentum phase properties for long-distance transmission, IEEE Access, 7 , 62689-62694 (2019).

[114] F. Xiao, G. Wang, X. Gan, W. Shang, S. Cao, W. Zhu, T. Mei, M. Premaratne, and J. Zhao, Selective excitation of a three-dimensionally oriented single plasmonic dipole, Photonics Research, 7(6) , 693-698 (2019).

[113] W. Yuan, X. Liang, L. Zhang, J. Geng, W. Zhu, R. Jin, Rectangular grating waveguide slot array antenna for SATCOM applications, IEEE Transactions on Antennas and Propagation, 67 (6), 3869-3880 (2019).

[112]  K. Song, R. Ji, D. Shrestha, C. Ding, Y. Liu, W. Zhu, W. He, H. Liu, Y. Guo, Y. Tang, X. Zhao, and J. Zhou, High-efficiency and wide-angle versatile polarization controller based on metagratings, Materials, 12 (4), 623 (2019).

[111]  F. Xiao, G. Wang, W. Shang, W. Zhu, L. Han, T. Mei, M. Premaratne, and J. Zhao, Radial breathing modes coupling in plasmonic molecules, Optics Express, 27 (4), 5116-5124 (2019).

[110] W. Shang, F. Xiao, W. Zhu, L. Han, M. Premaratne, T. Mei, and J. Zhao, Unidirectional scattering exploited transverse displacement sensor with tunable extended measuring range, Optics Express, 27 (4), 4944-4955 (2019).

[109] Y. Yao, X. Liang, M. Zhu, W. Zhu, J. Geng, R. Jin, Analysis and experiments on reflection and refraction of orbital angular momentum waves, IEEE Transactions on Antennas and Propagation, 67 (4), 2085-2094 (2019).

[108] X. Liang, J. Ren, L. Zhang, C. He, J. Geng, W. Zhu, and R. Jin, Wideband circularly polarized antenna with dual-mode operation, IEEE Antennas and Wireless Propagation Letters, 18 (4), 767-770 (2019).

[107] K. Zhuang, J. Geng, K. Wang, H. Zhou, Y. Liang, X. Liang, W. Zhu, and R. Jin, Pattern reconfigurable antenna applying spoof surface plasmon polaritons for wide angle beam steering, IEEE Access, 7, 15444-15451 (2019).

[106] J. Liu, J. Geng, K. Wang, Z. Ding, J. Li, X. Zhao, R. Jin, X. Liang, and W. Zhu, A low-profile, directional, ultrawideband antenna, IEEE Antennas and Wireless Propagation Letters, 18 (2), 255-259 (2019).

[105] W. Yuan, X. Liang, L. Zhang, J. Geng, W. Zhu, and R. Jin, Grating ridged waveguide V-shaped slot array antenna for SATCOM applications, Electronics Letters, 55 (4), 170-172 (2019).

[104] J. Chen, X. Liang, C. He, A. Cao, L. Bai, W. Zhu, J. Geng, and R. Jin, Direction finding of linear frequency modulation signal with time modulated array, IEEE Transactions on Antennas and Propagation, 67 (4), 2841-2846 (2019).

[103] C. He, G. Yi, W. Zhu, X. Liang, J. Geng, and R. Jin, A novel radar based on two-element time modulated array, IEEE Geoscience and Remote Sensing Letters, 16 (4), 524-528 (2019).

[102] K. J. Si, D. Dong, Q. Shi, W. Zhu, M. Premaratne, and W. Cheng, Ultrathin Fresnel lens based on plasmene nanosheets, Materials Today, 23, 9-15 (2019).


-2018

[101] F. Xiao, Y. Ren, W. Shang, W. Zhu, L. Han, H. Lu, T. Mei, M. Premaratne, and J. Zhao, Sub-10 nm particle trapping enabled by a plasmonic dark mode, Optics Letters, 43, 3413-3416 (2018).

[100] C. He, J. Chen, X. Liang, J. Geng, W. Zhu, and R. Jin, High accuracy DOA estimation based on time modulated array with long and short base lines, IEEE Antennas and Wireless Propagation Letters, 17, 1391-1395 (2018)

[99] A. S. Baimuratov, T. P. Pereziabova, M. Y. Leonov, W. Zhu,  A. V. Baranov, A. V. Fedorov, Y. K. Gun’ko, and I. D. Rukhlenko,  Optically active semiconductor nanosprings for tunable chiral nanophotonics, ACS Nano, 12, 6203-6209 (2018)

[98] H. Qi, J. Geng, W. Zhu, L. Liu, Z. Ding, X. Liang, T. Fan, X. Fang, and R. Jin, An 8GHz front-end module with high-performance T/R Switch and LNA, Progress In Electromagnetics Research C, 82, 185-197 (2018)

[97] 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, 66, 3642-3652(2018)

[96] 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,  17, 933-936 (2018)

[95] 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, 17, 735-738 (2018)

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

[93] 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 absorption, Optics Express, 26 (4), 5052-5059 (2018)

[92] 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 Express, 26 (3), 3211-3220 (2018)

[91] 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,  17, 530-533 (2018)

[90] 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)

[89] 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 Research, 6 (3), 157-161 (2018)

[88] 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 Letters,  17 (2), 283-286 (2018)

[87] 戚贺, 耿军平, 王堃, 梁仙灵, 朱卫仁, 樊婷婷, 金荣洪, X波段高性能有源集成天线设计, 上海交通大学学报(自然版),52 (10), 1249-1254(2018)

[86] 朱茂华, 梁仙灵, 姚羽,耿军平, 朱卫仁, 金荣洪, 基于多环结构的八模态涡旋波微带天线, 电波科学学报,33 (4), 455-462 (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,33 (4), 496-503 (2018)


-2017

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

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

[82] 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)

[81] 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)

[80] 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)

[79] 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)

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

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

[76] 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)

[75] 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)

[74] 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)

[73] 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)

[72] 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 Letters, 16, 1127-1130 (2017)

[71] 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)

[70] 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)

[69] 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)

[68] 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)

[67] 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, 32 (6), 694-701 (2017)

[66] 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, 39 (1), 11-16, (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 waves, IEEE Photonics Journal, 8 (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 Express, 24, 18332-18339 (2016).

[60] W. Zhu,* F. Xiao, M. Kang, and M. Premaratne, Coherent perfect absorption in an all-dielectric metasurface, Applied 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 substrate, Plasmonics, 10,1663–1673 (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 Propagation, 2015, 982325, (2015).

[57]   H. Sun, Y. Huang, J. Li, W. Zhu, and G. Wen, Ultra-compact metamaterial absorber with low-permittivity dielectric substrate, Progress In Electromagnetics Research M, 41, 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 Express, 23, 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 Letters, 14, 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 sensing, Plasmonics, 10,881–886 (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 Origami, ACS Nano, 8, 11086-11093(2014).

[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 system, Applied 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 gradient, Optics 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 points, Physical 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 absorber, Optics 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 layer, Journal of Optics 16, 075003(2014)

[47]  W. Zhu,* I. D. Rukhlenko, F. Xiao, and M. Premaratne, Polarization conversion in U-shaped chiral metamaterial with four-fold symmetry breaking, Journal 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 metamaterial, Optics 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 antenna, AIP 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 Process, Chinese 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 array, International 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 composite, Applied 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 beam, Optics Express 22, 2132 (2014)


-2013

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

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

[38] I. D. Rukhlenko, V. Kalavally, W. Zhu, and M. Premaratne, Engineering optical nonlinearities in silicon-nanocrystal waveguides, Journal 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 SRRs, Applied 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 configuration, Journal of Optics 15, 125101 (2013)

[35]  W. Zhu, I. D. Rukhlenko, and M. Premaratne, Graphene metamaterial for optical reflection modulation, Applied 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 configuration, Journal of Optics 15, 055104 (2013)

[33]  W. Zhu, I. D. Rukhlenko, L. Si, and M. Premaratne, Graphene-enabled tunability of optical fishnet metamaterial, Applied 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 metamaterial, Optics Express 21, 7439-7446 (2013)

[31]  L. Si, W. Zhu, and H. Sun, A compact, planar, and CPW-fed metamaterial-inspired dual-band antenna, IEEE 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 structure, IEEE Photonics Technology Letters 25 519-522 (2013)

[29]  W. Zhu, I. D. Rukhlenko, and M. Premaratne, Application of zero-index metamaterials for surface plasmon guiding, Applied 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 configuration, Journal 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 ferrite, Journal 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 waveguides, Optics 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 metamaterials, Journal of Electromagnetic Waves and Applications 26, 2315-2322 (2012)

[23] W. Zhu, I. D. Rukhlenko, and M. Premaratne, Linear transformation optics for plasmonics, Journal 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 index, Journal 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 stubs, IEEE 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 inserts, Applied 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 waveguide, Chinese Physics B 21, 117801 (2012)

[18]  W. Zhu, I. D. Rukhlenko, and M. Premaratne, Maneuvering propagation of surface plasmon polaritons using complementary medium inserts, IEEE 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 spectrum, Optics Express 20, 6616-6621 (2012)


-2011

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

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

[14]  W. Zhu, I. Shadrivov, D. Powell, and Y. Kivshar, Hiding in the corner, Optics 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 configuration, Journal 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 cells, Applied 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 metamaterials, Applied 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 patches, Chinese Physics Letters 27, 014204 (2010)

[8]    W. Zhu, and X. Zhao, Metamaterial absorber with random dendritic cells, The 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 dimension, Journal of Applied Physics 106, 093511 (2009)

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

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

[4]    W. Zhu, and X. Zhao, Numerical study of low-loss cross left-handed metamaterials at visible frequency, Chinese 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 structures, Applied 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 cells, Advanced Functional Materials 18, 3523-3528 (2008)

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