Relativistic electron motion in cylindrical waveguide with strong guiding magnetic field and high power microwave

We found that the electron drift length, L1, between a diode area and a resonant reflector in a relativistic backward wave oscillator operating at a low guiding magnetic field has a periodical influence on device power, which is a special characteristic due to periodical transverse motions of electron beams. In this paper, electron motion characteristics under both TM02 and TM01 fields are investigated using single-particle simulation, and the result shows that the condition of beam expansion is dependent on the beam state that spatially meets the TM02 standing-wave field. A larger beam expansion will lead to a larger axial energy spread in the modulation area, which is unfavorable for efficient beam-wave interaction. Furthermore, rapid transverse expansion of electron beams can be observed under a TM01 travelling-wave field, which is the main cause for the obvious decline in the current collected by the collector as the output power reaches saturation.

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Effects of transverse electron beam motion in a relativistic backward wave oscillator operating at low guiding magnetic field

Wang

Xiao

Chen

et al. 2020

AIP Advances

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Research on effects of space charge field in relativistic backward wave oscillator

Sun

Chen

et al. 2020

Physics of Plasmas

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The breakdown problem in the relativistic backward wave oscillator (RBWO) limits the microwave pulse energy and should be solved. The slow wave structure (SWS) is the most key component of the RBWO. The breakdown of SWS may be triggered by field-induced electron emission and electron bombardment on the wall. This paper demonstrates that the space charge field of the relativistic electron beam (REB) can enhance the electric field forbidding field-induced electron emission and decrease the electric field igniting the RF breakdown, and therefore, the RF breakdown can be significantly suppressed. However, the enhanced electric field will enlarge the radial displacements of electrons, especially the high-energy electrons. When the RBWO operates with a low guiding magnetic field or a long-pulse REB, this situation will worsen and some electrons may possess large enough radial displacements and bombard on the SWS surface with the help of radial oscillation of REB and radial expansion of cathode plasmas. This may aggravate the breakdown of SWS.

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Relativistic electron motion in cylindrical waveguide with strong guiding magnetic field and high power microwave

Cited by 2 publications

References 21 publications

Effects of transverse electron beam motion in a relativistic backward wave oscillator operating at low guiding magnetic field

Effects of transverse electron beam motion in a relativistic backward wave oscillator operating at low guiding magnetic field

Research on effects of space charge field in relativistic backward wave oscillator

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