• Українська
  • English
  • Русский
ISSN 2415-3400 (Online)
ISSN 1028-821X (Print)

INFLUENCE OF THE CRYSTAL LATTICE DIELECTRIC CONSTANT OF CONDUCTIVE MEDIUM ON THE RESONANCE INTERACTION OF ELECTROMAGNETIC WAVES IN THE DEFECT PHOTONIC CRYSTAL–CONDUCTOR STRUCTURE

heading: 
SOLID-STATE AND PLASMA RADIOPHYSICS
Beletskii, NN, Borysenko, SA, Gvozdev, NI
Organization: 

O. Ya. Usikov Institute for Radiophysics and Electronics of the National Academy of Sciences of Ukraine
12, Proskura st., Kharkov, 61085, Ukraine
E-mail: beletski@ire.kharkov.ua
https://doi.org/10.15407/rej2015.01.062
Language: Russian
Abstract: 

The defect photonic crystals bordering on the solid-state plasma-like media are worthy of special attention. These structures are of interest due to the occurrence of the plasma and defective waves which can interact resonantly with each other.  The effect of resonance interaction of different types of electromagnetic waves in defective photonic crystals is not adequately investigated. In this paper, the resonance interaction of plasma and defective TM-electromagnetic waves in a one-dimensional defect dielectric photonic crystal, bordering on the solid-state plasma-like medium, is studied on the basis of the numerical solution of the dispersion equation. The dispersive and energy properties of plasma and defective waves are investigated in accordance with the dielectric constant of the crystal lattice of the solid-state plasma-like medium. It is found that the resonance interaction of plasma and defective waves depends strongly on the type of solid-state plasma-like media. It is established that the effect of resonance interaction between the plasma and the defective waves takes place when the defective photonic crystal borders on the semiconductor plasma.   It is shown that the resonance interaction of plasma and defective waves disappears in the case when the defective photonic crystal borders on metal. The results of the study extend significantly our knowledge about the nature of the resonance interaction of plasma and defective waves in defect photonic crystals. The obtained results can be used in developing new devices of microelectronics and photonics.
Keywords: defect photonic crystal, defect waves, dielectric constant of crystal lattice, plasma-like medium, resonance interaction

Manuscript submitted 15.12.2014
PACS 41.20.Jb
Radiofiz. elektron. 2015, 20(1): 62-67
Full text (PDF)

References: 
  1. Vinogradov, A. P., Dorofeenko, A. V., Erokhin, S. G., Inoue, M., Lisyansky, A. A., Merzlikin, A. M. and Granovsky, A. B., 2006. Surface state peculiarities in one-dimensional photonic crystal interfaces. Phys. Rev. B. 74(4), pp. 045128 (8 p.).
  2. Goto, T., Dorofeenko, A. V., Merzlikin, A. M., Baryshev, A. V., Vinogradov, A. P., Inoue, M., Lisyansky, A. A., Granovsky, A. B., 2008. Optical Tamm States in One-Dimensional Magnetophotonic Structures. Phys. Rev. Lett. 101(11), pp. 113902 (3 p.).
  3. Vinogradov, A. P., Dorofeenko, A. V., Merzlikin, A. M., Lisyansky, A. A., 2010. Surface states in photon crystals. Usp. Fiz. Nauk. 180(3), pp. 249–263 (in Russian).DOI:https://doi.org/10.3367/UFNr.0180.201003b.0249
  4. Belozorov, D. P., Khodzitskiy, M. K. and Tarapov, S. I., 2009. Tamm states in magnetophotonic crystals and permittivity of wire medium. J. Phys. D.: Appl. Phys. 42(5), pp. 055003 (5 p.).
  5. Bass, F. G. and Tetervov, A. P., 1986. High-frequency phenomena in semiconductor superlattices. Phys. Rep. 140(5), pp. 237–322.DOI: https://doi.org/10.1016/0370-1573(86)90083-9
  6. Kaliteevski, M., Iorsh, I., Brand, S., Abram, R. A., Chamberlain, J. M., Kavokin, A. V. and Shelykh, I. A., 2007. Tamm plasmon-polaritons: Possible electromagnetic states at the interface of a metal and a dielectric Bragg mirror Phys. Rev. B. 76(16), pp. 165415 (5 p.).
  7. Sasin, M. E., Seisyan, R. P., Kaliteevski, M. A., Brand, S., Abram, R. A., Chamberlain, J. M., Egorov, A. Yu., Vasil’ev, A. P., Mikhrin, V. S. and Kavokin, A. V., 2008. Tamm plasmon-polaritons: Slow and spatially compact light Appl. Phys. Lett. 92(25), pp. 251112 (3 p.).
  8. Sasin, M. E., Seisyan, R. P., Kaliteevski, M. A., Brand, S., Abram, R. A., Chamberlain, J. M., Iorsh, I. V., Shelykh, I. A., Egorov, A. Yu., Vasil’ev, A. P., Mikhrin, V. S., Kavokin, A. V., 2010. Tamm plasmon-polaritons: First experimental observation. Super-lattices and Microstructures. 47(1), pp. 44–49.DOI: https://doi.org/10.1016/j.spmi.2009.09.003
  9. Belozorov, D. P., Khodzitskiy, M. K., and Tarapov, S. I., 2009. Tamm states in magnetophotonic crystals and permittivity of the wire medium. J. Phys. D. 42(5), pp. 055003 (5 p.).
  10. Averkov, Yu. O., Beletskii, N. N. and Yakovenko, V. M., 2011. Dependence of frequencies of the surface electromagnetic states in photonic crystals on parameters of duoble-layered dielectric elementary cell. Radiofizika i elektronika. 2(16)(2), pp. 40–47 (in Russian).
  11. Averkov, Yu. O., Beletskii, N. N. and Yakovenko, V. M., 2012. Surface electromagnetic waves in plasma-like medium bordering on a periodic layered structure. Radiofizika i elektronika, 3(17)(2), pp. 54–62 (in Russian).
  12. Beletskii, N. N., Borysenko, S. A., Gvozdev, N. I., 2013. Interaction of plasma and defective modes in one-dimensional layered periodic dielectric structures bordering upon plasma-like media. Radiofizika i elektronika, 4(18)(3), pp. 55–63 (in Russian).
  13. Beletskii, N. N., Borysenko, S. A., and Gvozdev, N. I., 2014. The resonant interaction of electromagnetic waves in a defect dielectric periodic layered structure placed in a parallel-plate waveguide. Radiofizika i elektronika, 5(19)(2), pp. 61–67 (in Russian).