Search search
Publication Date
to
Vol. 15
Latest Volume
All Volumes
PIERB 117 [2026] PIERB 116 [2026] PIERB 115 [2025] PIERB 114 [2025] PIERB 113 [2025] PIERB 112 [2025] PIERB 111 [2025] PIERB 110 [2025] PIERB 109 [2024] PIERB 108 [2024] PIERB 107 [2024] PIERB 106 [2024] PIERB 105 [2024] PIERB 104 [2024] PIERB 103 [2023] PIERB 102 [2023] PIERB 101 [2023] PIERB 100 [2023] PIERB 99 [2023] PIERB 98 [2023] PIERB 97 [2022] PIERB 96 [2022] PIERB 95 [2022] PIERB 94 [2021] PIERB 93 [2021] PIERB 92 [2021] PIERB 91 [2021] PIERB 90 [2021] PIERB 89 [2020] PIERB 88 [2020] PIERB 87 [2020] PIERB 86 [2020] PIERB 85 [2019] PIERB 84 [2019] PIERB 83 [2019] PIERB 82 [2018] PIERB 81 [2018] PIERB 80 [2018] PIERB 79 [2017] PIERB 78 [2017] PIERB 77 [2017] PIERB 76 [2017] PIERB 75 [2017] PIERB 74 [2017] PIERB 73 [2017] PIERB 72 [2017] PIERB 71 [2016] PIERB 70 [2016] PIERB 69 [2016] PIERB 68 [2016] PIERB 67 [2016] PIERB 66 [2016] PIERB 65 [2016] PIERB 64 [2015] PIERB 63 [2015] PIERB 62 [2015] PIERB 61 [2014] PIERB 60 [2014] PIERB 59 [2014] PIERB 58 [2014] PIERB 57 [2014] PIERB 56 [2013] PIERB 55 [2013] PIERB 54 [2013] PIERB 53 [2013] PIERB 52 [2013] PIERB 51 [2013] PIERB 50 [2013] PIERB 49 [2013] PIERB 48 [2013] PIERB 47 [2013] PIERB 46 [2013] PIERB 45 [2012] PIERB 44 [2012] PIERB 43 [2012] PIERB 42 [2012] PIERB 41 [2012] PIERB 40 [2012] PIERB 39 [2012] PIERB 38 [2012] PIERB 37 [2012] PIERB 36 [2012] PIERB 35 [2011] PIERB 34 [2011] PIERB 33 [2011] PIERB 32 [2011] PIERB 31 [2011] PIERB 30 [2011] PIERB 29 [2011] PIERB 28 [2011] PIERB 27 [2011] PIERB 26 [2010] PIERB 25 [2010] PIERB 24 [2010] PIERB 23 [2010] PIERB 22 [2010] PIERB 21 [2010] PIERB 20 [2010] PIERB 19 [2010] PIERB 18 [2009] PIERB 17 [2009] PIERB 16 [2009] PIERB 15 [2009] PIERB 14 [2009] PIERB 13 [2009] PIERB 12 [2009] PIERB 11 [2009] PIERB 10 [2008] PIERB 9 [2008] PIERB 8 [2008] PIERB 7 [2008] PIERB 6 [2008] PIERB 5 [2008] PIERB 4 [2008] PIERB 3 [2008] PIERB 2 [2008] PIERB 1 [2008]
All Journals
PIER PIER B PIER C PIER M PIER Letters
2009-07-01
Resonant Scattering of Electromagnetic Wave by Stripe Grating Backed with a Layer of Metamaterial
By
Andrey Brovenko,

    Dr. Andrey Brovenko

    Institute of Radiophysics and Electronics of National Academy of Sciences of Ukraine

    Ukraine

    Homepage

Petr Melezhik,

    Dr. Petr Melezhik

    Institute of Radiophysics and Electronics of National Academy of Sciences of Ukraine

    Ukraine

    Homepage

Anatoly Poyedinchuk,

    Dr. Anatoly Poyedinchuk

    Department of diffraction theory and diffraction electronics

    Institute of Radiophysics and Electronics of National Academy of Sciences of Ukraine

    Ukraine

    Homepage

Nataliya Yashina,

    Dr. Nataliya Yashina

    O.Ya. Usikov Institute for Radiophysics and Electronics, National Academy of Sciences of Ukraine

    Ukraine

    Homepage

Gerard Granet

    Professor Gerard Granet

    Universite Blaise Pascal

    France

    Homepage

Progress In Electromagnetics Research B, Vol. 15, 423-441, 2009
doi:10.2528/PIERB09052302 | Google Scholar

Abstract
Scattering of electromagnetic waves by periodic stripe grating backed with a layer of metamaterial is considered. The distinguished feature of the structure is the association of periodicity of two scales: Micro scale that is the scale characteristic to metamaterial of the layer, and the scale of periodic metal stripe grating that is of the scale of wavelength of incident electromagnetic field. Such association gives rise to new type of resonant phenomena such as "crowding" of resonant transmission/reflection peaks in the vicinity of characteristic frequencies of the structure. The study of the problem is performed on the base of rigorous and accurate solution to the diffraction and spectral problems, which guarantees the robustness of numerical algorithm; and allows asymptotical analytical analysis of the problem and prediction of various resonant phenomena.
Download Full Article (227) View Full Article volume
Citation
Andrey Brovenko, Petr Melezhik, Anatoly Poyedinchuk, Nataliya Yashina, and Gerard Granet, "Resonant Scattering of Electromagnetic Wave by Stripe Grating Backed with a Layer of Metamaterial," Progress In Electromagnetics Research B, Vol. 15, 423-441, 2009.
doi:10.2528/PIERB09052302
References

1. Pendry, J. B., "Negative refraction," Contemporary Physics, Vol. 45, No. 3, 191-203, 2004.
doi:10.1080/00107510410001667434        Google Scholar

2. Bilotti, F., A. Alu, N. Engheta, and L. Vegni, "Anomalous properties of scattering from cavities partially loaded with double-negative or single-negative metamaterials," Progress In Electromagnetics Research, Vol. 51, 49-63, 2005.
doi:10.2528/PIER04041401        Google Scholar

3. Lapine, M. and S. Tretyakov, "Contemporary notes on metamaterials," IET Microwaves, Antennas and Propagation, Vol. 1, No. 1, 3-11, 2007.
doi:10.1049/iet-map:20050307        Google Scholar

4. Lim, S., C. Caloz, and T. Itoh, "Electronically scanned composite right/left hfnded vicrostrip leaky-wave antenna," IEEE Microwave and Wireless Components Letters, Vol. 14, No. 6, 277-279, 2004.
doi:10.1109/LMWC.2004.828008        Google Scholar

5. Antoniades, M. A. and G. V. Eleftheriades, "Compact linear lead/lag metamaterial phase shifters for broadband applications," IEEE Antennas and Wireless Propagation Letters, Vol. 2, 103-106, 2003.
doi:10.1109/LAWP.2003.815280        Google Scholar

6. Engheta, N., "An idea for thin sub wavelength cavity resonators using metamaterials with negative permittivity and permeability," IEEE Antennas and Wireless Propagation Letters, Vol. 1, No. 1, 10-13, 2002.
doi:10.1109/LAWP.2002.802576        Google Scholar

7. Leskova, T. A., A. A. Maradudin, E. E. Garcia-Guerrero, and E. R. Mendez, "Structured surfaces as optical metamaterials," Metamaterials, Vol. 1, No. 1, 19-40, 2007.
doi:10.1016/j.metmat.2007.02.002        Google Scholar

8. Pendry, J. B., A. J. Holden, W. J. Stewart, and I. Youhgs, "Extremely low frequency plasmons in metallic structures," Phys. Rev. Letters, Vol. 76, 4773-4776, 1996.
doi:10.1103/PhysRevLett.76.4773        Google Scholar

9. Shestopalov, V. P. and Y. K. Sirenko, Dynamic Theory of Gratings, 214, Kiyev, Naukova Dumka, 1989.

10. Brovenko, A., P. Melezhik, and A. Poyedinchuk, "The method of regularization for one class of dual series equations," Ukrainskiy Matematichesskiy Zhurnal, Vol. 53, No. 10, 1320-1327, 2001 (in Russian).        Google Scholar

11. Brovenko, A., P. Melezhik, and A. Poyedinchuk, "Diffraction of plane electromagnetic wave by metal grating with magnetoactive plazma," Izvestiya VUZov, Radiofizika, Vol. 47, No. 8, 638-649, 2004 (in Russian).        Google Scholar

12. Shestopalov, V. P., Method of Riemann-Hilbert Problem in Theory of Electromagnetic Wave Diffraction and Propagation, 400, Kharkov, Publishing House of Kharkov University, 1971 (in Russian).

13. Shestopalov, V. P., Y. A. Tuchkin, A. Y. Poyedinchuk, and Y. K. Sirenko, "Novel methods of solving of direct and inverse problems of diffraction theory," Analytical Regularization of Boundary Value Problems in Electromagnetics, 285, Kharkov, Osnova, 1997 (in Russian).        Google Scholar

14. Gohberg, I. C. and Y. I. Sigal, "Operator generalization of the theorem about logarithm residue and Rouche's theorem," Matematicheskiy Sbornik, Vol. 84, No. 4, 607-629, 1971 (in Russian).        Google Scholar

15. Brovenko, A., P. N. Melezhik, A. Y. Poyedinchuk, and N. P. Yashina, "Surface resonances of metal stripe grating on the plane boundary of metamaterial ," Progress In Electromagnetics Research, Vol. 63, 209-222, 2006.
doi:10.2528/PIER06052401        Google Scholar

16. Sirenko, Y. K., S. Strom, and N. P. Yashina, "Modeling and analysis of transient progresses in open resonant structures," New Methods and Techniques, 353, Springer, 2007.        Google Scholar

Download Full Article (227) View Full Article volume


The EM Academy piers.org jpier.org Who's Who in EM
Copyright © 2022 The Electromagnetics Academy. All Rights Reserved.