MAGNETO-ELECTRO-OPTICALLY CONTROLLED MICROWAVE INTERFEROGRAM OF A META-INTERFEROMETER WITH A METASTRUCTURE AS A BEAM SPLITTER

Kraftmakher, G.A.; Butylkin, V.S.; Fisher, P.S.; Kazantsev, Yu.N.; Kalenov, D.S.; Mal'tsev, V.P.

doi:10.7868/S3034590125060029

PII

S30345901S0033849425060029-1

DOI

10.7868/S3034590125060029

Publication type

Article

Status

Published

Authors

G.A. Kraftmakher

Affiliation: Fryazino Branch Kotelnikov Institute of Radioengineering and Electronics RAS

V.S. Butylkin

Affiliation: Fryazino Branch Kotelnikov Institute of Radioengineering and Electronics RAS

P.S. Fisher

Affiliation: Fryazino Branch Kotelnikov Institute of Radioengineering and Electronics RAS

Yu.N. Kazantsev

Affiliation: Fryazino Branch Kotelnikov Institute of Radioengineering and Electronics RAS

D.S. Kalenov

Affiliation: Fryazino Branch Kotelnikov Institute of Radioengineering and Electronics RAS

V.P. Mal'tsev

Affiliation: Fryazino Branch Kotelnikov Institute of Radioengineering and Electronics RAS

Volume/ Edition

Volume 70 / Issue number 6

Pages

547-555

Abstract

In a modified interferometer based on a waveguide tee with a controlled beam splitter (a metastructure containing a ferrite plate + a butterfly dipole loaded with a varactor), a combined effect on the interferogram of ferromagnetic resonance (FMR) controlled by an external magnetostatic field H and electro-optically controlled dipole resonance (DR) was experimentally detected in the range of 3...6 GHz. The non-reciprocity of microwave transmission in the FMR, DR, and interference exclusion bands was found, characterized by a change in the transmission coefficient T during inversion of H, and magneto-electro-optical control using a remote laser pointer was demonstrated when using the photodiode mode in the varactor/photodiode scheme. The functional capabilities of a meta-interferometer in photovoltaic mode and direct fiber-optic control with a semiconductor-loaded metastructure based on linear resonant dipoles are shown.

Keywords

мета-интерферометр микроволновая интерферограмма метаструктура диполь «бабочка» варактор ферритовая пластина фотодиод ферромагнитный и дипольный резонансы невзаимность фотодиодный и фотогальванический режим прямое волоконно-оптическое управление

Date of publication

09.12.2025

Year of publication

2025

Number of purchasers

Views

References

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GOST	Butylkin V., Fisher P., Kalenov D., Kazantsev Y., Kraftmakher G., Mal'tsev V. MAGNETO-ELECTRO-OPTICALLY CONTROLLED MICROWAVE INTERFEROGRAM OF A META-INTERFEROMETER WITH A METASTRUCTURE AS A BEAM SPLITTER // Journal of Communications Technology and Electronics. – 2025. – V. 70. – Issue number 6 C. 547-555 . URL: https://radiotechras.ru/s30345901s0033849425060029-1/?version_id=120424. DOI: 10.7868/S3034590125060029
MLA	Butylkin, V.S, Fisher, P.S, Kalenov, D.S, Kazantsev, Yu.N, Kraftmakher, G.A, Mal'tsev, V.P "MAGNETO-ELECTRO-OPTICALLY CONTROLLED MICROWAVE INTERFEROGRAM OF A META-INTERFEROMETER WITH A METASTRUCTURE AS A BEAM SPLITTER." Journal of Communications Technology and Electronics. 70.6 (2025).:547-555. DOI: 10.7868/S3034590125060029
APA	Butylkin V., Fisher P., Kalenov D., Kazantsev Y., Kraftmakher G., Mal'tsev V. (2025). MAGNETO-ELECTRO-OPTICALLY CONTROLLED MICROWAVE INTERFEROGRAM OF A META-INTERFEROMETER WITH A METASTRUCTURE AS A BEAM SPLITTER. Journal of Communications Technology and Electronics. vol. 70, no. 6, pp.547-555 DOI: 10.7868/S3034590125060029

RAS PhysicsРадиотехника и электроника Journal of Communications Technology and Electronics

MAGNETO-ELECTRO-OPTICALLY CONTROLLED MICROWAVE INTERFEROGRAM OF A META-INTERFEROMETER WITH A METASTRUCTURE AS A BEAM SPLITTER

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RAS PhysicsРадиотехника и электроника Journal of Communications Technology and Electronics

MAGNETO-ELECTRO-OPTICALLY CONTROLLED MICROWAVE INTERFEROGRAM OF A META-INTERFEROMETER WITH A METASTRUCTURE AS A BEAM SPLITTER

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