Plasma expansion and impedance collapse in a foil-less diode for a klystronlike relativistic backward wave oscillator

Xiao, Renzhen; Sun, Jun; Huo, Shaofei; Li, Xiaoze; Zhang, Ligang; Zhang, Xiaowei; Zhang, Lijun

doi:10.1063/1.3520072

Cited by 26 publications

(10 citation statements)

References 15 publications

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“…In the relativistic terahertz devices, a Bragg reflector is used to reflect the signal. 21 By using this mode, a reflector which takes the place of the previous tapered section is adopted to shorten the distance from the electron gun to the main SWS. In our design, a section of the slotted sine waveguide is used as the novel reflector to reflect the signal.…”

Section: Backward Wave Oscillator Performancementioning

confidence: 99%

Investigation of 0.38 THz backward-wave oscillator based on slotted sine waveguide and pencil electron beam

et al. 2016

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A novel backward wave oscillator (BWO) is presented by utilizing a slotted sine waveguide with a pencil electron beam to produce the high power terahertz wave. The high frequency characteristics including dispersion properties, interaction impedances, and transmission characteristics of the slotted sine waveguide are analyzed in detail. The high frequency system including the output coupler, slow wave structure (SWS), and reflector are designed properly. A 3-D particle-in-cell mode is applied to predict the device performance of the BWO based on the novel SWS. The investigation results demonstrate that this device can generate over 8.05 W output power in the frequency range of 363.4-383.8 GHz by using a 30 mA pencil electron beam and adjusting the beam voltage from 20 kV to 32 kV. V

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Section: Backward Wave Oscillator Performancementioning

confidence: 99%

Investigation of 0.38 THz backward-wave oscillator based on slotted sine waveguide and pencil electron beam

et al. 2016

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“…erefore, foilless diodes are well capable of high-power density, long pulsed, and repetitive operated applications, such as high-power microwave devices and microsecond pulse electron accelerators [9]. e axial foilless diodes immersed in solenoid magnetic field are widely used in O-type high-power microwave devices [15][16][17][18], as shown in Figure 1. e advantage of the structure is that the diode cathode is completely immersed in the uniform strong magnetic field of solenoid coil, which is conducive to the generation of high-quality annular electron beams.…”

Section: Introductionmentioning

confidence: 99%

“…In the development of high-power microwave system, low power consumption and miniaturization are important conditions for the practical application [19][20][21]. However, the traditional foilless diode structure has the following disadvantages [17,[22][23][24]: (a) in order to avoid excessive radial electric field, the radius of drift tube is usually large, which makes the size of inner wall of solenoid coil much larger than that of microwave device and drift tube, resulting in waste of excitation space; (b) if the diode is to be further miniaturized, it is necessary to reduce the distance between diode cathode and drift tube wall, and this change will lead to the enhancement of the electric field intensity on the cathode emitter, which is very easy to cause the radial emission of electrons on the cathode, thus causing the loss of electron energy. Some electrons even form reverse motion, bombarding the insulator and damaging the insulation system [22]; (c) moreover, the volume, weight, and energy consumption of solenoid coil and auxiliary power equipment are large, which is not conducive to the application on mobile platforms.…”

Section: Introductionmentioning

confidence: 99%

An Axial Foilless Diode Guided by Composite Magnetic Field for the Production of Relativistic Electron Beams

Xiao

Wang

et al. 2021

Laser Part. Beams

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Foilless diode are widely used in high-power microwave devices, but the traditional foilless diodes have large volume, heavy weight, and high power consumption, which are not conducive to the application of high-power microwave system on mobile platform. In order to reduce the size of the foilless diode, improve the transmission efficiency of electron beams, and reduce the weight and power consumption of the guiding magnetic field system, an axial foilless diode with a composite guiding magnetic field system is developed in this paper. By adjusting the structure size and magnetic field parameters of solenoid coil, permanent magnet, and soft magnet, the configuration of the composite magnetic field is optimized. The diameter of the anode tube is about 40% smaller than that of the original structure, and the weight and power consumption of the guiding magnetic system are about 40% lower than that of the original system when the same axial magnetic field intensity in the uniform region is generated. When the magnetic field strength of the permanent magnet is set as 1.4 T and that of the solenoid coil is in the range of 0.5 T∼1 T, the electron beam transmission efficiency is 100%, and the diode impedance is adjustable in the range of 100 Ω∼240 Ω. The experimental results verify the correctness of the simulation analysis. The experimental results show that when the magnetic field strength of the solenoid coil is 0.98 T (0.5 T) and that of the permanent magnet is 1.4 T, the transmission efficiency of the high-current annular electron beam with a peak voltage of 636 kV (590 kV) and a peak current of 3.3 kA (2.6 kA) is 100%, and the diode impedance is about 194 Ω (220 Ω).

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“…[1][2][3][4][5][6][7][8][9][10][11] To further increase the beam-wave interaction efficiency and output power, in our earlier work we introduced a klystron-like RBWO combining transition radiation with Cerenkov radiation. [12][13][14] In that device, a resonant reflector was used before the slow wave structure (SWS) to reflect backward wave and premodulate the electron beam; a modulation cavity separated the SWS to decrease the energy spread of the modulated beam electrons; and an extraction cavity was added to recover energy from the beam. The beam dump was located very close to the extraction cavity to provide more kinetic energy for extraction.…”

Section: Introductionmentioning

confidence: 99%

High efficiency coaxial klystron-like relativistic backward wave oscillator with a premodulation cavity

Xiao¹,

Teng²,

Chen³

et al. 2011

Physics of Plasmas

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The klystron-like relativistic backward wave oscillator (RBWO) combines the transition radiation with Cerenkov radiation and has demonstrated microwave output of high power and high efficiency. The coaxial slow wave structure device can produce microwave with a lower frequency in a smaller cross section. For the purpose of high efficiency, low frequency, and miniaturization, a coaxial klystron-like RBWO with a premodulation cavity is presented. Particle-in-cell simulations show that a microwave with power of 1.15 GW and frequency of 2.1 GHz is generated with conversion efficiency of 48%, whereas for the device with a reflector, the efficiency is 38%.

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Plasma expansion and impedance collapse in a foil-less diode for a klystronlike relativistic backward wave oscillator

Cited by 26 publications

References 15 publications

Investigation of 0.38 THz backward-wave oscillator based on slotted sine waveguide and pencil electron beam

Investigation of 0.38 THz backward-wave oscillator based on slotted sine waveguide and pencil electron beam

An Axial Foilless Diode Guided by Composite Magnetic Field for the Production of Relativistic Electron Beams

High efficiency coaxial klystron-like relativistic backward wave oscillator with a premodulation cavity

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