Highly efficient X-band relativistic twistron; Laser and Particle Beams; Vol. 34, iss. 4

Highly efficient X-band relativistic twistron; Laser and Particle Beams; Vol. 34, iss. 4

Podrobná bibliografie
Parent link:	Laser and Particle Beams Vol. 34, iss. 4.— 2016.— [P. 601-605]
Hlavní autor:	Totmeninov E. M. Evgeny Markovich
Korporativní autor:	Национальный исследовательский Томский политехнический университет (ТПУ) Институт физики высоких технологий (ИФВТ) Кафедра сильноточной электроники (СЭ)
Další autoři:	Pegel I. V. Igor Valerievich, Tarakanov V. P. Vladimir Pavlovich
Shrnutí:	Title screen The paper proposes a new scheme of high-power microwave oscillator of twistron type using a moderately relativistic high-current electron beam. In numerical experiment using axisymmetric version of the completely electromagnetic PiC code KARAT, a 56% conversion efficiency of electron beam power to electromagnetic radiation was demonstrated. With 340 kV accelerating voltage, 3.3 kA electron beam current, and 2.2 T guiding magnetic field strength, the simulated microwave power was 630 MW at 9.7 GHz. The “electronic efficiency” of the source reaches 66%. Режим доступа: по договору с организацией-держателем ресурса
Jazyk:	angličtina
Vydáno:	2016
Témata:	электронный ресурс труды учёных ТПУ
On-line přístup:	https://doi.org/10.1017/S0263034616000537
Médium:	Elektronický zdroj Kapitola
KOHA link:	https://koha.lib.tpu.ru/cgi-bin/koha/opac-detail.pl?biblionumber=653033

Podobné jednotky

Relativistic Cherenkov Microwave Oscillator Without a Guiding Magnetic Field for the Electron-Beam Energy of 0.5 MeV; IEEE Transactions on Plasma Science; Vol. 38, iss. 10
Autor: Totmeninov E. M. Evgeny Markovich
Vydáno: (2010)

Experimental Investigation of the Relativistic CherenkovMicrowave Oscillator Without a Guiding Magnetic Fieldat the Electron Energy 0.5 MeV; 16th Symposium on High Current Electronics, September 19-24, 2010
Autor: Totmeninov E. M. Evgeny Markovich
Vydáno: (2010)

Generation of runaway electrons and X rays in an inhomogeneous electric field at high gas pressures; Laser and Particle Beams; Vol. 34, iss. 4
Vydáno: (2016)

Frequency-tunable relativistic coaxial backward-wave oscillator with a modulating reflector; Technical Physics; Vol. 60, iss. 3
Autor: Totmeninov E. M. Evgeny Markovich
Vydáno: (2015)

Relativistic Cherenkov Microwave Oscillator Without a Guiding Magnetic Field; IEEE Transactions on Plasma Science; Vol. 37, iss. 7
Autor: Totmeninov E. M. Evgeny Markovich
Vydáno: (2009)

On reduction of transient process duration in a relativistic Cherenkov microwave oscillator without a guiding magnetic field; Technical Physics; Vol. 61, iss. 6
Autor: Totmeninov E. M. Evgeny Markovich
Vydáno: (2016)

Plasma-filled diode with a rod anode for repetitive pulsed X-ray sources; Laser and Particle Beams; Vol. 34, iss. 4
Autor: Kovalchuk B. M. Boris Mikhailovich
Vydáno: (2016)

Energy spectrum analysis for intense pulsed electron beam; Laser and Particle Beams; Vol. 34, iss. 4
Vydáno: (2016)

High-intensity pulsed ion beam focusing by its own space charge; Laser and Particle Beams; Vol. 36, iss. 4
Vydáno: (2018)

Generation and transportation of high-intensity pulsed ion beam at varying background pressures; Laser and Particle Beams; Vol. 35, iss. 4
Vydáno: (2017)

Relativistic Nonlinear Electrodynamics. Interaction of Charger Particles with Strong and Super Strong Laser Fields
Vydáno: (Berlin, Springer, 2006)

Guest Editor's Foreword; Laser and Particle Beams; Vol. 21, № 2
Autor: Mesyats G. A. Gennady Andreyevich
Vydáno: (2003)

Comparison of Influence of the Fast Atom Beam and Ion Beam on the Metal Target; Laser and Particle Beams; Vol. 2021
Vydáno: (2021)

Repetitively pulsed high-current accelerators with transformer charging of forming lines; Laser and Particle Beams; Vol. 21, № 2
Vydáno: (2003)

Formation of high-power, high-voltage rectangular pulses with the controlled stabilization of the pulse peak; Laser and Particle Beams; Vol. 35, iss. 1
Autor: Petrov A. V. Anatoly Viktorovich
Vydáno: (2017)

Modification of copper surface by runaway electronspreionized diffuse discharges at atmospheric pressure; Laser and Particle Beams; Vol. 34, iss. 2
Vydáno: (2016)

High-intensity pulsed ion beam composition and the energy spectrum using the time-of-flight method; Laser and Particle Beams; Vol. 36, iss. 2
Autor: Pushkarev A. I. Aleksandr Ivanovich
Vydáno: (2018)

Extending the range of measurement of thermal imaging diagnostics of a high-intensity pulsed ion beam; Laser and Particle Beams; Vol. 37, iss. 3
Vydáno: (2019)

Coaxial moderately relativistic L-band backward wave oscillator; 3rd International Congress on Radiation Physics and Chemistry of Condensed Matter, High Current Electronics and Modification of Materials with Particle Beams and Plasma Flows
Vydáno: (2012)

A multigigawatt X-Band relativistic backward wave oscillator with a modulating resonant reflector; Technical Physics Letters; Vol. 34, iss. 3
Vydáno: (2008)

Compact millimeter-range microwave oscillators with high-current relativistic electron beams; Program abstracts of the 9th International Conference on High-Power Particle Beams: BEAMS'92, Washington DC, may 25-29, 1992
Autor: Mesyats G. A. Gennady Andreyevich
Vydáno: (1992)

Applicability of the 1D Child–Langmuir relation for ion diode current calculation; Laser and Particle Beams; Vol. 34, iss. 2
Autor: Pushkarev A. I. Aleksandr Ivanovich
Vydáno: (2016)

Generation, transport, and efficient extraction of a large cross-section electron beam into an air in an accelerator with a mesh plasma cathode; Laser and Particle Beams; Vol. 36, iss. 1
Vydáno: (2018)

Reconstruction of electron beam energy spectra for vacuumand gas diodes; Laser and Particle Beams; Vol. 33, № 2
Vydáno: (2015)

The influence of a shield on intense ion beam transportation; Laser and Particle Beams; Vol. 31, iss. 3
Autor: Pushkarev A. I. Aleksandr Ivanovich
Vydáno: (2013)

A 5.107-A/kg dose rate compact X-ray generator; Laser and Particle Beams; Vol. 7 pt. 4
Vydáno: (1989)

Diffraction Radiation from Relativistic Particles
Vydáno: (New York, Springer, 2010)

UV and IR laser radiation's interaction with metal film and teflon surfaces; Laser and Particle Beams; Vol. 21, № 2
Vydáno: (2003)

Muon Beam Channeling in Laser Standing Wave; Charged and Neutral Particles Channeling Phenomena
Autor: Babaev A. A. Anton Anatoljevich
Vydáno: (2016)

Calculation and optimization of topology of a radial insulating magnetic field in an acceleration gap of a high-power ion diode with an induction plasma source; Laser and Particle Beams; Vol. 34, № 2
Vydáno: (2016)

A Possibility of Pulsed Power Increasingof X-Band Relativistic Backward Wave Oscillator; 15th Symposium on High Current Electronics, September 21-26, 2008
Vydáno: (2008)

Repetitive X -Band Relativistic Traveling Wave Oscillator; IEEE Transactions on Electron Devices; Vol. 64, iss. 5
Vydáno: (2017)

Study on ablation products of zinc by intense pulsed ion beam irradiation; Laser and Particle Beams; Vol. 35, iss. 1
Vydáno: (2017)

Review of studies of superradiative microwave generation in X band and Ka band relativistic BWOs; IEEE Transactions on Plasma Science; Vol. 32, iss. 3, pt. 1
Vydáno: (2004)

Experimental demonstration of coherent power summation for relativistic x-band HPM oscillators; 16th International Symposium on High Current Electronics, Tomsk, 19-24 September 2010
Vydáno: (2010)

Primary energy storages based on linear transformer stages; Laser and Particle Beams; Vol. 21, № 2
Vydáno: (2003)

Band Structure of Transverse Energy Levels of Relativistic PlanarChanneled e- and e+; Charged and Neutral Particles Channeling Phenomena. Channeling 2014
Autor: Eykhorn Yu. L. Yury Leonidovich
Vydáno: (2014)

High-power wide-aperture electron-beam-pumped lasers on dense gases; Laser Physics; Vol. 16, No. 1
Vydáno: (2006)

The physics of charged-particle beams
Autor: Lawson J. D.
Vydáno: (Oxford, Clarendon Press, 1978)

Effect of emission increasing at the generation of low-energy submillisecond electron beam in the diode with the plasma cathodel; High Power Particle Beams (BEAMS)
Vydáno: (2008)