The influences of beam quality and Ohmic loss on the beam-wave interaction in a 420 GHz second-harmonic complex-cavity gyrotron

Zhao, Qixiang; Shen, Yu

doi:10.1209/0295-5075/118/38002

Cited by 4 publications

(1 citation statement)

References 32 publications

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“…Furthermore, for studying the interaction efficiency influenced by realistic electron beam in the working point, the transverse velocity spread has been considered and researched in the self‐consistent numerical simulation of beam‐wave interaction. In the simulation, a Gaussian distribution is used to characterize the transverse velocity spread based on the theory described in References and . The results are presented in Figure .…”

Section: The Hot‐cavity Analysismentioning

confidence: 99%

Design and analysis on a 0.1‐THz second harmonic low‐voltage, low‐current gyrotron with complex cavity

Zhang²,

Zhang

et al. 2020

Micro & Optical Tech Letters

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This article presents the design and analysis of a complex cavity that will be used in a 10 kW‐level 94 GHz second harmonic low‐current, low‐voltage gyrotron. The mode pair of TE+7.2/TE+7.3 is selected as the operating modes of the complex cavity. In cold‐cavity design, a throat is introduced in the complex cavity to increase the diffractive quality factor, which can make the gyrotron operate at low‐current and low‐voltage conditions. In hot‐cavity analysis, the beam‐wave interaction efficiency affected by different factors has been studied in detail. At the operating point with beam voltage of 32 kV and beam current of 1.5 A, the mode competition has been studied based on the analysis of starting current and a time‐dependent multifrequency code; the transverse velocity spread influence on the efficiency has also been investigated. The results indicate that the operating mode eventually dominates the mode selection, while the competing modes are all at noise level. Meanwhile, the interaction efficiency can keep more than 30% with maintaining the spread below 8%, and the output power can hold at 10 kW‐level when the spread is below 12%.

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Section: The Hot‐cavity Analysismentioning

confidence: 99%

Design and analysis on a 0.1‐THz second harmonic low‐voltage, low‐current gyrotron with complex cavity

Zhang²,

Zhang

et al. 2020

Micro & Optical Tech Letters

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State-of-the-Art of High-Power Gyro-Devices and Free Electron Masers

Thumm

2020

J Infrared Milli Terahz Waves

307

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STATE-OF-THE-ART OF HIGH POWER GYRO-DEVICES AND FREE ELECTRON MASERSAt present, gyrotron oscillators are mainly used as high power millimeter wave sources for electron cyclotron resonance heating (ECRH) and diagnostics of magnetically confmed plasmas for generation of energy by controlled thermonuclear fusion. 140 GHz gyrotrons with output power Pout = 0.58 MW, pulse length 't = 2.0 s and efficiency 11 = 34 % are commercially available. Diagnostic gyrotrons deliver P out = 40 kW with 't = 40 J-lS at frequencies up to 650 GHz (11 2_ 4 %). Recently, gyrotron oscillators have also been successfully used in matedal processing and plasma chemistry. Such technological applications require gyrotrons with the following parameters: f 2. 28 GHz , Pout = 10-30 kW, CW, 11 2. 30 %. This paper reports on achievements and problems related to the development of very high power mm-wave gyrotrons for long pulse or CW operation and describes the microwave technological pecularities of the different development steps. In addition, this work gives a short overview of the present development of gyrotrons for technological applications, quasi-optical gyrotrons, cyclotron autoresonance masers (CARMs), gyro-ldystrons, gyro-TWT amplifiers, gyro-BWO's and free electron masers (FEMs). The most impressive FEM output parameters are: Pout = 2GW, 't = 20 ns, 11 = 13 % at 140 GHz (LLNL) and Pout = 15 kW, 't = 20 J-tS, 11 = 5 % in the range from 120 to 900 GHz (UCSB). ENTWICKLUNGSSTAND VON HOCHLEISTUNGS-GYRO-RÖHREN UND FREI-ELEKTRONEN-MASERN Übersiebt Gyrotronoszillatoren werden derzeit vorwiegend als Hochleistungsmillimeterwellenquellen für die Elektron-Zyklotron-Resonanzheizung (ECRH) und Diagnostik von magnetisch eingeschlossenen Plasmen zur Erforschung der Energiegewinnung durch kontrollierte Kernfusion eingesetzt. 140 GHz Gyrotrons mit einer Ausgangsleistung von Pout = 0.58 MW bei Pulslängen von 't = 2.0 s und Wirkungsgraden von • 11 = 34% sind kommerziell erhältlich. Gyrotrons zur Plasmadiagnostik erreichen Frequenzen bis zu 650 GHz bei P out = 40 kW und 't = 40 ~-ts (11 2. 4 %). In jüngster Zeit jedoch finden Gyrotronoszillatoren auch für technologische Prozesse und in der Plasmachemie erfolgreich Verwendung. Dabei werden Röhren mit folgenden Parametern eingesetzt: f 2_ 28 GHz, Pout = 10-30 kW, CW, 11 2. 30 %. In diesem Beitrag wird auf den aktuellen Stand und die Probleme bei der Entwicklung von Hochleistungs-mm-Wellen-Gyrotrons für Langpuls-und Dauerstrichbetrieb sowie auf die mikrowellentechnischen Besonderheiten der einzelnen Entwicklungsphasen eingegangen: Außerdem wird auch kurz über den neuesten Stand der Entwicklung von Gyrotrons für technologische Anwendungen, quasi-optischen Gyrotrons, Zyklotron-Autoresonanz-Masern (CARMs), Gyroklystrons, Gyro-TWT-Verstärkern, Gyro-Rückwärtswellenoszillatoren (BWOs) und Frei-Elektronen-Maser (FEM) berichtet. FEM-Rekordausgangsparameter sind hier: Pout = 2 GW, 't = 20 ns, 11 = 13 % bei 140 GHz (LLNL) und Pout = 15 kW, 't = 20 J-lS, 11 = 5 % im Bereich von 120 bis 900 GHz (UCSB). Contents

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Reflection influence on the operation of a 0.42 THz second harmonic gyrotron with complex cavity

Zhao

Shen

2017

Vacuum

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The influences of beam quality and Ohmic loss on the beam-wave interaction in a 420 GHz second-harmonic complex-cavity gyrotron

Cited by 4 publications

References 32 publications

Design and analysis on a 0.1‐THz second harmonic low‐voltage, low‐current gyrotron with complex cavity

Design and analysis on a 0.1‐THz second harmonic low‐voltage, low‐current gyrotron with complex cavity

State-of-the-Art of High-Power Gyro-Devices and Free Electron Masers

Reflection influence on the operation of a 0.42 THz second harmonic gyrotron with complex cavity

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