Zhurnal Radioelektroniki - Journal of Radio Electronics. eISSN 1684-1719. 2022. №8
Contents

Full text in Russian (pdf)

DOI: https://doi.org/10.30898/1684-1719.2022.8.6

PLASMON ORIGIN OF STANDING WAVES
INTO NEAR FIELD BEHIND HOLEY METALLIC SLABS

I.A. Karpov

Institute of Solid States Physics of RAS
142432, Russia, Chernogolovka, Academician Ossipyan str. 2

The paper was received June 22, 2022

Abstract. This paper is devote to research of microwave electric field patterns behind multilayer metamaterial fishnet structures and multilayer one-dimensional arrays of apertures into near field, closely to holey surface of specimens. Microwave near field patterns of electric field amplitude showed standing waves pictures by some frequencies closely to holey metallic surfaces. May expect that these standing waves serve as the sequent of interference from different plasmon modes which emerge on holey metallic surfaces of slabs as well as into dielectric gaps between them.

Key words: metamaterial, fishnet structure, holey metallic slabs, apertures, dielectric gap, multilayer structures, microwave electric field pattern, near field, surface plasmons, spoof surface plasmons.

Corresponding author: Karpov Igor' Anatol'evich, karpow@issp.ac.ru

References

1. Ebbesen T.W., Lezec H.J., Ghaemi H.F., Thio T., Wolff P.A. Extraordinary optical transmission through sub-wavelength hole arrays. Nature. 1998. V.391. P.667-669.

2. Mary A., Rodrigo Sergio G., Martin-Moreno L., Garcia-Vidal F. J. Plasmonic metamaterials based on holey metallic films. Journal of Physics: Condensed Matter. 2008. V.20. P.304215. https://doi.org/10.1088/0953-8984/20/30/304215

3. Hajian Hodjat, Ozbay Ekmel, Caglayan Humeyra Beaming and enhanced transmission through a subwavelength aperture via epsilon-near-zero media. Nature, Scientific Reports. 2017. V.7. P.4741. https://doi.org/10.1038/s41598-017-04680-y

4. Butler Celia A.M., Parsons James, Sambles J. Roy, Hibbins Alastair P., Hobson Peter A. Microwave transmissivity of a metamaterial–dielectric stack. Applied Physics Letters. 2009. V.95. P.174101. https://doi.org/10.1063/1.3253703

5. Pendry J.B., Martín-Moreno L., García-Vidal F.J. Mimicking Surface Plasmons with Structured Surfaces. Science. 2004. V.305. P.847-848.

6. Garcia-Vidal F.J., Martin-Moreno L., Pendry J.B. Surfaces with holes in them: new plasmonic metamaterials. Journal of Optics A: Pure and Applied Optics. 2005. V.7. P.97-101. https://doi.org/10.1088/1464-4258/7/2/013

7. Hibbins Alastair P., Lockyear Matthew J., Sambles J. Roy Surface Plasmons on Metamaterials. Proceedings of SPIE – The International Society for Optical Engineering (Society of Photo-Optical Instrumentation Engineers). 2008. V.6987. Article 698712. https://doi.org/10.1117/12.780247

8. Economou E. N. Surface Plasmons in Thin Films. Physical Review. 1969. V.182. №2. P.539-554.

9. Karpov I.A., Shoo E.D. New equipment for microwave electric field visualization. Review of Scientific Instruments. 2012. V.83. P.074704. https://doi.org/10.1063/1.4737495

10. Karpov I.A., Shoo E.D. Metamaterial “magnetic” coating on microwaves. Zhurnal radioelectroniki [Journal of Radio Electronics]. 2014. №4. http://jre.cplire.ru/jre/apr14/9/text.html (In Russian)

11. Karpov I.A. Passing of microwaves through multilayer metamaterial-dielectric structure: near field and far field. Zhurnal radioelectroniki [Journal of Radio Electronics]. 2018. №12. https://doi.org/10.30898/1684-1719.2018.12.19
(In Russian)

For citation:

Karpov I.A. Plasmon origin of standing waves into near field behind holey metallic slabs. Zhurnal radioelectroniki [Journal of Radio Electronics] [online]. 2022. №8. https://doi.org/10.30898/1684-1719.2022.8.6 (In Russian)