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Theoretical and experimental analysis of waveguide containing transversally magnetized strongly gyrotropic dissipative semiconductor layer

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Abstract

In this paper we present the Maxwell equations' solution method enabling to electrodynamically rigorously compute opened and screened waveguides containing transversally magnetized gyrotropic material. There have been theoretically and experimentally analysed a rectangular metal waveguide having along the narrow wall a gyrotropic dissipative layer ofn-InSb. There has been found the resonant waveguide losses' dependence on the magnitude of the biasing magnetic field. The correspondence of computed and experimental data is fairly good.

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Authors and Affiliations

  1. Semiconductor Physics Institute, A. Goštauto 11, 2600, Vilnius, Lithuania

    I. Burneika, L. Knishevskaya, K. Pozhela, O. Smertin & M. Tamoshiunene

  2. Vilnius University Physics Faculty Sauletekio 9, 2054, Vilnius, Lithuania

    V. Shugurov

Authors
  1. I. Burneika
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  2. L. Knishevskaya
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  3. K. Pozhela
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  4. O. Smertin
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  5. M. Tamoshiunene
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  6. V. Shugurov
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Burneika, I., Knishevskaya, L., Pozhela, K. et al. Theoretical and experimental analysis of waveguide containing transversally magnetized strongly gyrotropic dissipative semiconductor layer. Int J Infrared Milli Waves 17, 185–192 (1996). https://doi.org/10.1007/BF02088192

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  • DOI: https://doi.org/10.1007/BF02088192

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