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On the observed energy of runaway electron beams in air

Published online by Cambridge University Press:  15 December 2011

G.A. Mesyats ,
A.G. Reutova ,
K.A. Sharypov ,
V.G. Shpak ,
S.A. Shunailov  and
M.I. Yalandin
G.A. Mesyats
Affiliation:
P. N. Lebedev Physical Institute, Russian Academy of Sciences, Moscow, Russia
A.G. Reutova
Affiliation:
Institute of Electrophysics, Ural Division, Russian Academy of Sciences, Ekaterinburg, Russia
K.A. Sharypov
Affiliation:
Institute of Electrophysics, Ural Division, Russian Academy of Sciences, Ekaterinburg, Russia
V.G. Shpak
Affiliation:
Institute of Electrophysics, Ural Division, Russian Academy of Sciences, Ekaterinburg, Russia
S.A. Shunailov
Affiliation:
Institute of Electrophysics, Ural Division, Russian Academy of Sciences, Ekaterinburg, Russia
M.I. Yalandin*
Affiliation:
Institute of Electrophysics, Ural Division, Russian Academy of Sciences, Ekaterinburg, Russia
*
Address correspondence and reprint requests to: Michael I. Yalandin, Institute of Electrophysics, UD RAS, 106 Amundsen Street, 620016, Ekaterinburg, Russia. E-mail: yalandin@iep.uran.ru
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Abstract

Experiments with an air electrode gap have been performed where the current/charge of a picosecond beam of runaway electrons was measured over a wide range (up to four orders of magnitude) downstream of the absorbing foil filters. Measurements and calculations have made it possible to refer the beam current to the rise time of the accelerating voltage pulse to within picoseconds. It has been shown that, in contrast to a widespread belief, the runaway electron energies achieved are no greater than those corresponding to the mode of free acceleration of electrons in a nonstationary, highly nonuniform electric field induced by the cathode voltage. The experimental data agree with predictions of a numerical model that describes free acceleration of particles. It has been confirmed that the magnitude of the critical electric field that is necessary for electrons to go into the mode of continuous acceleration of electrons in atmospheric air corresponds to classical notions.

Keywords

Accelerating voltageContinuous accelerationCut-off energyFoil filterRunaway electrons
Type
Research Article
Information
Laser and Particle Beams , Volume 29 , Issue 4 , December 2011 , pp. 425 - 435
Copyright
Copyright © Cambridge University Press 2011

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References

REFERENCES

Babich, L.P. & Loiko, T.V. (2010). Peculiarities of detecting pulses of runaway electrons and X-rays generated by high-voltage nanosecond discharges in open atmosphere. Plasma Phys. Reports. 36, 263270.CrossRefGoogle Scholar
Babich, L.P., Loiko, T.V. & Tsukerman, V.A. (1990). High-voltage nanosecond discharge in dense gases developing with runaway electrons regime under high over voltages. Uspekhi Fizicheskikh Nauk. (Rus.) 160, 4982.Google Scholar
Baksht, E.H., Burachenko, A.G., Kozyrev, A.V., Kostyrya, I.D., Lomaev, M.I., Petin, V.K., Rybka, D.V., Tarasenko, V.F. & Shljakhtun, S.V. (2009). Spectra of electrons and X-ray photons in a diffusive nanosecond discharge in air under atmospheric pressure. Techn. Phys. 54, 4755.CrossRefGoogle Scholar
Baranov, V.F. (1974). Dozimetry of Eletronic Radiation. Moscow: Atomizdat.Google Scholar
Dreicer, H. (1959). Electron and ion runaway in a fully ionized gas. Phys. Rev. 115, 238249.Google Scholar
Gurevich, A.V. (1960). On the theory of the effect of runaway electrons. Zh. Eksper. Teor. Fiz. (Rus.) 39, 12961301.Google Scholar
Korolev, Yu.D. & Mesyats, G.A. (1998). Physics of Pulsed Breakdown in Gases. Yekaterinburg: UD RAS.Google Scholar
Mesyats, G.A. & Yalandin, M.I. (2009). On the nature of picosecond runaway electron beams in air. IEEE 37, 785789.Google Scholar
Mesyats, G.A., Korovin, S.D., Rostov, V.V., Shpak, V.G. & Yalandin, M.I. (2004). The RADAN series of compact pulsed power generators and their applications. IEEE 92, 11661179.Google Scholar
Mesyats, G.A., Korovin, S.D., Sharypov, K.A., Shpak, V.G., Shunaillov, S.A. & Yalandin, M.I. (2006). Dynamics of subnanosecond electron beam formation in gas-filled and vacuum diodes. Techn. Phys. Lett. 32, 1822.CrossRefGoogle Scholar
Mesyats, G.A., Shpak, V.G., Shunailov, S.A. & Yalandin, M.I. (2008 b). Electron source and acceleration regime of a picosecond electron beam in a gas-filled diode with inhomogeneous field. Techn. Phys. Lett. 34, 169173.Google Scholar
Mesyats, G.A., Yalandin, M.I., Sharypov, K.A., Shpak, V.G. & Shunailov, S.A. (2008 a). Generation of a picosecond runaway electron beam in a gas gap with a nonuniform field. IEEE 36, 24972504.Google Scholar
Morugin, L.A. & Glebovitch, G.V. (1964). Pulsed Nanosecond Technique. Moscow: Sov. Radio.Google Scholar
Reutova, A.G., Mesyats, G.A., Sharypov, К.А., Shpak, V.G., Shunailov, S.A. & Yalandin, M.I. (2010). The stability of runaway electron beam characteristics in gas diode with non-uniform electric field. Proc. of 16th Int. Symp. on High Current Electronics, pp. 102105. Tomsk: HCEI SB RAS.Google Scholar
Reutova, A.G., Sharypov, K.A., Shpak, V.G., Shunailov, S.A. & Yalandin, M.I. (2008). Current Probes for Picosecond Eelectron Beams. Proc. of 15th Int. Symp. on High Current Electronics, pp. 111114. Tomsk: HCEI SB RAS.Google Scholar
Sharypov, K.A., Shpak, V.G., Shunailov, S.A. & Yalandin, M.I. (2008). The measurements of picosecond gas discharge parameters. Proc. of 15th Int. Symp. on High Current Electronics, pp. 360363. Tomsk: HCEI SB RAS.Google Scholar
Tarakanov, V.P. (1992). User's Manual for Code KARAT. Springfield: Berkeley Research Associates.Google Scholar
Tiunov, M.A., Fomel, B.M. & Yakovlev, V.P. (1989). SAM-an Interactive Code for Electron Gun Evaluation. Novosibirsk: INP-89–159.Google Scholar
Yakovlenko, S.I. (2006). Generation of anomalous electrons during high-voltage nanosecond breakdown in dense gases. Techn. Phys. Lett. 32, 330332.CrossRefGoogle Scholar
Yalandin, M.I. & Shpak, V.G. (2001). Compact high-power subnanosecond repetitive-pulse generators. Instr. Exper. Techn. 44, 285310.Google Scholar
Yalandin, M.I., Reutova, A.G., Sharypov, K.A., Shpak, V.G., Shunailov, S.A. & Mesyats, G.A. (2010 b). Moment of injection of runaway electrons at the front of accelerating pulse in air-filled diode with inhomogeneous field: from instability to determinacy. Techn. Phys. Lett. 36, 830833.CrossRefGoogle Scholar
Yalandin, M.I., Reutova, A.G., Sharypov, K.A., Shpak, V.G., Shunailov, S.A., UImasculov, M.R., Rostov, V.V. & Mesyats, G.A. (2010 a). Stability of injection of a subnanosecond high-current electron beam and dynamic effects within its risetime. IEEE 38, 25592564.Google Scholar
Zagulov, F.Ya., Kotov, A.S., Shpak, V.G., Yurike, Ya.Ya. & Yalandin, M.I. (1989). The RADAN series of compact high-current periodic-pulse electron-accelerators. Instr.Exper. Techn.32, 420423.Google Scholar