Design and Numerical Analysis of W-band Oscillators With Hollow Electron Beam

The use of hollow electron beams permits a significant increase in the diameter of the beam tunnel in comparison with the conventional pencil-beam slow-wave electron devices. As a result, the current density and the heating of the microwave structure are decreased, which allows increasing the averag...

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Bibliographic Details
Published inIEEE transactions on electron devices Vol. 61; no. 6; pp. 1795 - 1799
Main Authors Bratman, Vladimir L., Fedotov, Alexey E., Makhalov, Petr B., Manuilov, Vladimir N.
Format Journal Article
LanguageEnglish
Published New York IEEE 01.06.2014
The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Subjects
Backward-wave oscillator (BWO)
Cavity resonators
Corrugation
Devices
Electromagnetic heating
Electron beams
Electrons
hollow electron beam
Mathematical analysis
Mathematical model
Microwave oscillators
Microwaves
orotron
Orotrons
Oscillators
Power generation
Simulation
slow-wave device
slow-wave device
hollow electron beam
Backward-wave oscillator (BWO)
orotron
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Summary:The use of hollow electron beams permits a significant increase in the diameter of the beam tunnel in comparison with the conventional pencil-beam slow-wave electron devices. As a result, the current density and the heating of the microwave structure are decreased, which allows increasing the average radiation power at high frequencies. To demonstrate this capability, two versions of W-band oscillators, namely, an axisymmetric orotron and a backward-wave oscillator (BWO), have been designed. The electron beam with an outer diameter of 1.6 mm and a 0.1-mm thick wall could be produced in a 30 kV/1 A Pierce-like electron gun with the hundredfold magnetic compression. Oscillators use microwave structures with an azimuthally symmetric corrugation, sinusoidal for the orotron and rectangular for the BWO. Simulations based on the averaged equations and 3-D PIC-code predict an output power up to 1 kW for the orotron and 0.7 kW for the BWO, whereas the thermal regime in the BWO is easier for continuous-wave operation. Wideband frequency tuning of the BWO is simulated. To reduce ohmic losses, a smooth downtaper of the corrugation in the orotron and an abrupt cutoff with a specially optimized last tooth in the BWO were designed.
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ISSN:0018-9383
1557-9646
DOI:10.1109/TED.2014.2309397