代表性论文

1.A. Q.   Zhang, Z. G. Liu,  W. B. Lu* and   H. Chen,”Graphene-Based Dynaically Tunable Attenuator on a Coplanar Waveguide   or a Slotline”, IEEE Trans. on MTT, vol. 67, no. 1, pp. 70-77, 2019.

2.W.   Xiang, T. Xiong,  W. B. Lu*, W.   Yang and Z. G. Liu,”New Accurate Sub-Entire-Domain Basis Functions Method for   the Analysis of Large-scale Finite Periodic Structures with Electrically   Connected Cells”, IEEE Trans. on AP, doi:10.1109/TAP.2018.2889609.

3.A. Q.   Zhang, Z. G. Liu,  W. B. Lu* and   H. Chen, “Dynamically Tunable Attenuator on Graphene Based Microstrip Line”,   IEEE Trans. on MTT, vol. 67, no. 2, pp. 746-753, 2019.

4.H.   Chen, Z. G. Liu, W. B. Lu*, A. Q.   Zhang, X. B. Li, J. Zhang, “Microwave Beam Reconfiguration Based on Graphene   Ribbon”, IEEE Trans. on AP, vol. 66. no. 11, pp. 6049-6056, 2018.

5.H. Chen,   W. B. Lu*, Z. G.   Liu, J. Zhang, A. Q. Zhang, B. Wu,”Experimental Demonstration of Microwave   Absorber Using Large-Area Multilayer Graphene-Based Frequency Selective   Surface”, IEEE Trans. on MTT, vol. 66, no. 8, pp. 3807-3816, 2018.

6.A.   Q. Zhang, W. B. Lu*, Z. G. Liu，“Dynamically   Tunable Substrate-Integrated Waveguide Attenuator Using Graphene，” IEEE   Trans. on MTT, vol. 66, no. 6, pp.   3081-3089, 2018.

7.A.   Q. Zhang, W. B. Lu*, Z. G. Liu，“Graphene-based   dynamically tunable attenuator on a half-mode substrate integrated waveguide,”Applied   Physics Letters,  vol.112,   161903, 2018.

8.B.   H. Huang, W. B. Lu*, Z. G. Liu，“Low-energy   high-speed plasmonic enhanced modulator using graphene,” Optics Express, vol.26,   no.6, 7358, 2018

9.B. Wu,  Y. Hu, Y. T. Zhao, W. B. Lu, “Large angle   beam steering THz antenna using active frequency selective surface based on   hybrid graphene-gold structure,” Optics Express, vol. 26,   no. 12, 15353, 2018.

10.H.   Chen, W. B. Lu＊,   Z. G. Liu, J. Zhang and B. H. Huang,”Efficient manipulation of spoof surfae   palsmon polaritions based on rotated complementary H-Shaped resonator   metasurface,”  IEEE Trans. on AP   , vol. 65, no. 12, pp. 7383-7388, 2017

11.Z.   G. Liu, W. B. Lu＊,   W. Yang, Enhanced bandwidth of highly directive emission Fabry-Perot   resonator antenna with tapered effective near-zero index using   metasurface, Scientific Reports, 7:11455，   2017

12.Z.   G. Liu, W. B. Lu＊,   Low-Profile Design of Broadband High Gain Circularly Polarized   Fabry-Perot Resonator Antenna and its Array with Linearly Polarized   Feed, IEEE Access, vol. 5, pp. 7164-7172, 2017

13.Z.   G. Liu, W. B. Lu＊,   Broadband Design of Circularly Polarized High Gain Fabry-Perot   Resonator Antenna with Simple Array Thinning Technique, Microwave and   optical technology lett., vol. 59, no. 12, pp.3171-3176, 2017.

14.W.   B. Lu＊,   J. L. Liu, J. Zhang and Z. G. Liu,”   Polarization-independent transparency window induced by complementary   graphene metasurfaces”，   Journal of Physics D: Applied Physics, vol. 50, no. 1, pp. 015106, 2017.

15. B. H. Huang, W. B. Lu*, X. B. Li, J. Wang   and Z. G. Liu, “Waveguide-coupled hybrid plasmonic modulator based on   grapheme,” Applied Optics, vol. 55, no. 21,pp.5598, 2016

16.J.   Wang, W. B. Lu*, X. B. Li, and J. L. Liu, “Terahertz wavefront control based   on graphene manipulated Fabry-Pérotcavities,”IEEE Photonics Technology   Letters, vol. 28, no. 29, pp. 971-974, 2016.

17.J.   Wang, W. B. Lu*, J. L. Liu, and T. J. Cui, “Digital metamaterials using   graphene,” Plasmonics, vol. 10, no. 5, pp. 1141-1145, 2015.

18.J.   Wang, W. B. Lu*, X. B. Li, Z. H. Ni, and T. Qiu, “Grapheneplasmon guided   along a nanoribbon coupled with a nanoring,” Journal of Physics D: Applied   Physics, vol. 47, no. 13, pp. 135106, 2014.

19.J.   Hu, W. B. Lu*, and J. Wang, “Highly confined and tunable plasmonic waveguide   ring resonator based on grapheme nanoribbons,” Europhysics Letters, vol. 106,   no. 4, pp. 48002, 2014.

20.J.   Wang, W. B. Lu*, X. B. Li, X. F. Gu, and Z. G. Dong, “Plasmonic metamaterial   based on the complementary split ring resonators using graphene,” Journal of   Physics D: Applied Physics, vol. 47, no. 32, pp. 325102, 2014.

21.W.   B. Lu*, W. Zhu, H. J. Xu, Z. H. Ni, Z. G. Dong, and T. J. Cui, “Flexible   transformation plasmonics using graphene,” Optics Express, vol. 21, no. 9,   pp. 10475-10482, 2013.

22.X.   G. Luo, T. Qiu*, W. B. Lu*, and Z. H. Ni*, “Plasmons in graphene: Recent   progress and applications,” Materials Science and Engineering: R: Reports,   vol. 74, no. 11, pp. 351-376, 2013.

23.H.   J. Xu, W. B. Lu*, W. Zhu, Z. G. Dong, and T. J. Cui, “Efficient manipulation   of surface plasmon polariton waves in graphene,” Applied Physics Letters,   vol. 100, no. 24, pp. 243110, 2012.

24.H.   J. Xu, W. B. Lu*, Y. Jiang, and Z. G. Dong, “Beam-scanning planar lens based   on graphene,” Applied Physics Letters, vol. 100, no. 5, pp. 051903, 2012.

25.Y.   Jiang, W. B. Lu*, H. J. Xu, Z. G. Dong, and T. J. Cui, “A planar   electromagnetic “black hole”    based   on graphene,” Physics Letters A, vol. 376, no. 17, pp. 1468-1471, 2012.

26.W.   B. Lu*，Z.   F. Ji，Z.   G. Dong，X.   W. Ping，T.   J. Cui ，“Left   handed transmission properties of planar metamaterials based on complementary   double-ring resonators”，Journal   of Applied Physics，108（033717）。2010.

27.W.   B. Lu, T. J. Cui* , “Efficient   method for full-wave analysis of large-scale finite-sized periodic structures”，Journal   of Electromagnetic Waves and Applications，21（14）2157-2168，2007.

28.W.   B. Lu，T.   J. Cui* ，H.   Zhao，“Acceleration   of fast multipole method for large-scale periodic structures with finite   sizes using sub-entire-domain basis functions”，IEEE   Trans. on AP，55（2）414-421，2007.

29.Z.   G. Qian, T. J. Cui, W. B. Lu, X. X. Yin, W. Hong, and W. C. Chew, “An   improved MoM model for line-fed patch antennas and printed circuits,” IEEE   Trans. on AP, vol. 53, no. 9, pp.   2969-2976, 2005.

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