Experimental research of different plasma cathodes for generation of high-current electron beams

Shafir, G.; Kreif, Meytal; Gleizer, J. Z.; Gleizer, S.; Krasik, Ya. E.; Gunin, A. V.; Кутенков, О. П.; Pegel, I. V.; Rostov, V. V.

doi:10.1063/1.4935880

Cited by 36 publications

(8 citation statements)

References 20 publications

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“…The BWO is driven by a high-current relativistic electron beam generated in a magnetically insulated foilless diode under the application of a negative polarity high-voltage (HV) pulse, produced by a semiconductor-opening-switches (SOSs)-based generator 24 with an internal impedance of 200 X. The parameters of the diode and the generated electron beam were described previously, 25 where a generator producing HV pulses at a matched load of $220 kV, $6 ns at FWHM, and 1.5 ns risetime was used. In order to increase the electron beam energy, the SOS-based generator was modified, resulting in the HV pulses of $350 kV, $6 ns at FWHM, and $0.5 ns rise-time obtained after the gas spark-gap switch at the matched (200 X) load.…”

Section: Methodsmentioning

confidence: 99%

“…An explosive emission plasma, formed at the sharp boundary of the edged graphite cathode (diameter of 28 mm) under the application of an HV pulse, served as a source of electrons that produced a %0.5 mm-wide annular electron beam. 25 This beam was transported through the SWS using a guiding magnetic field B ¼ 2:5 T (axial nonuniformity of $1% along $70 cm length), with a half period of $4.4 ms, produced by an external solenoid.…”

Section: Methodsmentioning

confidence: 99%

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High power microwave source for a plasma wakefield experiment

Shafir

Shlapakovski

Siman-Tov

et al. 2017

Journal of Applied Physics

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The results of the generation of a high-power microwave ($550 MW, 0.5 ns, $9.6 GHz) beam and feasibility of wakefield-excitation with this beam in under-dense plasma are presented. The microwave beam is generated by a backward wave oscillator (BWO) operating in the superradiance regime. The BWO is driven by a high-current electron beam ($250 keV, $1.5 kA, $5 ns) propagating through a slow-wave structure in a guiding magnetic field of 2.5 T. The microwave beam is focused at the desired location by a dielectric lens. Experimentally obtained parameters of the microwave beam at its waist are used for numerical simulations, the results of which demonstrate the formation of a bubble in the plasma that has almost 100% electron density modulation and longitudinal and transverse electric fields of several kV/cm.

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Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

High power microwave source for a plasma wakefield experiment

Shafir

Shlapakovski

Siman-Tov

et al. 2017

Journal of Applied Physics

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“…The device consists of an all solid-state high-voltage (HV) generator based on magnetic compression stages and semiconductor opening switches 22 (not shown in Fig. 1), a magnetically insulated foilless diode with an explosive electron emitting graphite cathode, 23 a solenoid producing a guiding magnetic field sufficient for strong magnetization of the generated cylindrical electron beam, a specially designed slow wave structure (SWS), and a horn antenna.…”

Section: Microwave Beam Generation In a 28 Ghz Sr-bwo A Experimementioning

confidence: 99%

“…The HV generator (internal impedance of 200 X), described in Ref. 23, produces at its output a negative polarity of $320 kV and a rise-time pulse of $2.5 ns. To reduce the rise-time to $0.5 ns, a gas filled spark-gap switch is installed between the generator output and the cathode holder.…”

Section: Microwave Beam Generation In a 28 Ghz Sr-bwo A Experimementioning

confidence: 99%

Wakefield excitation by a powerful sub-nanosecond 28.6 GHz microwave pulse propagating in a plasma filled waveguide

et al. 2019

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High-power microwave pulse generation ($1.2 GW, $0.4 ns, 28.6 GHz) by a super-radiant backward wave oscillator (SR-BWO) and the feasibility of wakefield-excitation with this pulse in a plasma-filled waveguide are presented. The SR-BWO is driven by an electron beam ($280 keV, $1.5 kA, $5 ns) generated in a magnetically insulated foilless diode and propagating through a slowwave structure in a guiding magnetic field of 8 T. The plasma produced by an array of flashboards filling a cylindrical wire-array waveguide attached at the exit of the SR-BWO is also characterized. 1D and 3D numerical simulations demonstrate that for the experimental parameters of the microwave pulse and the flashboard plasma filling the waveguide, a wakefield forms accompanied by significant periodic density modulations such that their radial location and depth can be controlled by the waveguide radius, plasma density, and microwave power.

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“…A magnetically insulated foilless diode with a hollow graphite circular sharp-edged cathode is used to produce an annular electron beam [39]. The dimensions and exact location of the cathode are part of the design of each SR-BWO.…”

Section: The Experimentsmentioning

confidence: 99%

Experiments Designed to Study the Non-Linear Transition of High-Power Microwaves through Plasmas and Gases

Krasik

Leopold

Shafir

et al. 2019

Plasma

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The interaction of powerful sub-picosecond timescale lasers with neutral gas and plasmas has stimulated enormous interest because of the potential to accelerate particles to extremely large energies by the intense wakefields formed and without being limited by high accelerating gradients as in conventional accelerator cells. The interaction of extremely high-power electromagnetic waves with plasmas is though, of general interest and also to plasma heating and wake-field formation. The study of this subject has become more accessible with the availability of sub-nanosecond timescale GigaWatt (GW) power scale microwave sources. The interaction of such high-power microwaves (HPM) with under-dense plasmas is a scale down of the picosecond laser—dense plasma interaction situation. We present a review of a unique experiment in which such interactions are being studied, some of our results so far including results of our numerical modeling. Such experiments have not been performed before, self-channeling of HPM through gas and plasma and extremely fast plasma electron heating to keV energies have already been observed, wakefields resulting from the transition of HPM through plasma are next and more is expected to be revealed.

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Experimental research of different plasma cathodes for generation of high-current electron beams

Cited by 36 publications

References 20 publications

High power microwave source for a plasma wakefield experiment

High power microwave source for a plasma wakefield experiment

Wakefield excitation by a powerful sub-nanosecond 28.6 GHz microwave pulse propagating in a plasma filled waveguide

Experiments Designed to Study the Non-Linear Transition of High-Power Microwaves through Plasmas and Gases

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