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01-05-2019 | PHYSICAL ELECTRONICS

Bragg Deflectors of Wave Fluxes for High-Power Relativistic Masers

Authors: A. V. Arzhannikov, N. S. Ginzburg, V. Yu. Zaslavskii, P. V. Kalinin, N. Yu. Peskov, A. S. Sergeev, S. L. Sinitskii

Published in: Technical Physics | Issue 5/2019

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Abstract

Quasi-optical Bragg structures that represent sections of planar waveguides with tilted (with respect to the beam propagation direction) corrugation are studied. It is shown that such structures may serve as efficient deflectors for high-power wave fluxes and, hence, can be used for separation of microwave radiation and electron beam in relativistic masers. The corrugation configuration is optimized to increase the efficiency of transformation of wave fluxes to the transverse direction and improve uniformity of the spatial distribution of scattered radiation. The simulated results are verified using cold electrodynamic tests.

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Note different notations for the eigenwaves of the planar and rectangular waveguides. The lowest (TE_1,0) mode of the strongly elongated rectangular waveguide is transformed into the TEM mode of the planar waveguide when the side walls are removed.

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Title: Bragg Deflectors of Wave Fluxes for High-Power Relativistic Masers
Authors: A. V. Arzhannikov
N. S. Ginzburg
V. Yu. Zaslavskii
P. V. Kalinin
N. Yu. Peskov
A. S. Sergeev
S. L. Sinitskii
Publication date: 01-05-2019
Publisher: Pleiades Publishing
Published in: Technical Physics / Issue 5/2019
Print ISSN: 1063-7842
Electronic ISSN: 1090-6525
DOI: https://doi.org/10.1134/S1063784219050037

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