Chiral electromagnetic objects

B.Z. Katsenelenbaum^a, E.N. Korshunova^b, A.N. Sivov^b, A.D. Shatrov^b
^aInstitute of Radio Engineering and Electronics, Russian Academy of Sciences, ul. Mokhovaya 11, Moscow, 125009, Russian Federation
^bInstitute of Radio Engineering and Electronics, Russian Academy of Sciences, pl. Vvedenskogo 1, Fryazino, Moscow Region, 141120, Russian Federation

A review is presented of some recent theoretical results in the research and development work on artificial spatially dispersive media and on structures possessing chiral properties in the microwave range. The results discussed are mainly obtained for chiral objects taken in the form of long helices of small radius to wavelength ratio, and of arrays of such helices. These structures display strong polarization-selective resonance effects which give rise to a rich variety of their electrodynamic properties.

PACS: 41.20.Jb, 42.25.Ja, 78.90.+t, 84.40.Cb (all)
DOI: 10.1070/PU1997v040n11ABEH000306
URL: https://ufn.ru/en/articles/1997/11/c/
Web of Science

000071302300003
Citation: Katsenelenbaum B Z, Korshunova E N, Sivov A N, Shatrov A D "Chiral electromagnetic objects" Phys. Usp. 40 1149–1160 (1997)

BibTexBibNote ® (generic)BibNote ® (RIS)MedlineRefWorks

Оригинал: Каценеленбаум Б З, Коршунова Е Н, Сивов А Н, Шатров А Д «Киральные электродинамические объекты» УФН 167 1201–1212 (1997); DOI: 10.3367/UFNr.0167.199711c.1201

References (36) Cited by (59) Similar articles (20) ↓

V.G. Veselago “The electrodynamics of substances with simultaneously negative values of ε and μ” 10 509–514 (1968)
S.I. Vinitskii, V.L. Derbov et al “Topological phases in quantum mechanics and polarization optics” 33 (6) 403–428 (1990)
A.P. Pyatakov, A.K. Zvezdin “Magnetoelectric and multiferroic media” 55 557–581 (2012)
A.V. Gurevich “Nonlinear effects in the ionosphere” 50 1091–1121 (2007)
V.F. Kravchenko, A.A. Kuraev, A.K. Sinitsyn “Nonsynchronous interactions” 50 489–511 (2007)
A.V. Dorofeenko, A.A. Zyablovsky et al “Light propagation in composite materials with gain layers” 55 1080–1097 (2012)
S.A. Nemov, Yu.I. Ravich “Thallium dopant in lead chalcogenides: investigation methods and peculiarities” 41 735–759 (1998)
A.G. Kyurkchan, B.Yu. Sternin, V.E. Shatalov “Singularities of continuation of wave fields” 39 1221–1242 (1996)
S.Yu. Karpov, S.N. Stolyarov “Propagation and transformation of electromagnetic waves in one-dimensional periodic structures” 36 (1) 1–22 (1993)
S.A. Gredeskul, V.D. Freilikher “Localization and wave propagation in randomly layered media” 33 (2) 134–146 (1990)
A.V. Timofeev “Electromagnetic waves in a magnetized plasma near the critical surface” 47 555–582 (2004)
D.A. Kirzhnits “General properties of electromagnetic response functions” 30 575–587 (1987)
V.B. Shteinshleiger “Nonlinear scattering of radio waves by metallic objects” 27 60–68 (1984)
V.V. Zheleznyakov, V.V. Kocharovskii, V.V. Kocharovskii “Linear coupling of electromagnetic waves in inhomogeneous weakly-ionized media” 26 877–905 (1983)
A.A. Zyablovsky, A.P. Vinogradov et al “PT-symmetry in optics” 57 1063–1082 (2014)
B.M. Bolotovskii, S.N. Stolyarov “Current status of the electrodynamics of moving media (infinite media)” 18 875–895 (1975)
E.A. Kaner, V.G. Skobov “Electromagnetic waves in metals in a magnetic field” 9 480–503 (1967)
S.I. Pekar “Supplementary light waves in crystals and exciton absorption” 5 515–521 (1962)
V.P. Alfimenkov “Nonconservation of parity in the elastic neutron-nucleus interaction channel” 27 797–808 (1984)
N.D. Zhevandrov “Polarisation physiological optics” 38 1147–1166 (1995)

The list is formed automatically.