Experimental Study on G-Band Oversized Backward Wave Oscillator Driven by Weakly Relativistic Electron Beam

Shota MAGORI; Kazuo OGURA; Takayuki IWASAKI; Junpei KOJIMA; Kiyoyuki YAMBE; Shin KUBO; Takashi SHIMOZUMA; Sakuji KOBAYASHI; Kohji OKADA

doi:10.1585/pfr.9.3406032

Regular Articles

Experimental Study on G-Band Oversized Backward Wave Oscillator Driven by Weakly Relativistic Electron Beam

Shota MAGORI, Kazuo OGURA, Takayuki IWASAKI, Junpei KOJIMA, Kiyoyuki YAMBE, Shin KUBO, Takashi SHIMOZUMA, Sakuji KOBAYASHI, Kohji OKADA

Author information

Shota MAGORI
Graduate School of Science and Technology, Niigata University
Kazuo OGURA
Graduate School of Science and Technology, Niigata University
Takayuki IWASAKI
Graduate School of Science and Technology, Niigata University
Junpei KOJIMA
Graduate School of Science and Technology, Niigata University
Kiyoyuki YAMBE
Graduate School of Science and Technology, Niigata University
Shin KUBO
National Institute for Fusion Science
Takashi SHIMOZUMA
National Institute for Fusion Science
Sakuji KOBAYASHI
National Institute for Fusion Science
Kohji OKADA
National Institute for Fusion Science

Keywords: oversized backward wave oscillator, weakly relativistic electron beam, cold cathode, slow-wave structure, rectangular corrugation, G-band

JOURNAL FREE ACCESS

2014 Volume 9 Pages 3406032

DOI https://doi.org/10.1585/pfr.9.3406032

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Abstract

We studied a G-band oversized backward wave oscillator (BWO) driven by a weakly relativistic electron beam of less than 100 kV. Rectangular corrugations are used as slow-wave structures having surface waves with upper cutoff frequencies above 150 GHz (G-band). We examine how dispersion characteristics of surface waves are affected by accuracy in machining the corrugation amplitude, width, and period length. Of these, accuracy in the amplitude has the largest effect. Uniformly distributed annular electron beams are generated by a disk-type cold cathode and injected into the G-band BWO. G-band BWO operations in 137 - 173 GHz and above 173 GHz are achieved by changing the corrugation amplitude. The radiation patterns are fairly broad, and the estimated radiation power is at kW level.

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