Experimental study of the reduction of field emission by gas injection in vacuum for accelerator applications

Experimental study of the reduction of field emission by gas injection in vacuum for accelerator applications

Field emission current from surfaces under vacuum and at high field strengths can be reduced by the injection of gas into the evacuated volume. In this paper, the effects of H_{2}, He, N_{2}, and Ar on this “dark” current emitted from a tungsten carbide point cathode for 2 cm gap distance is studied...

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Main Authors: K. Almaksour, M. J. Kirkpatrick, Ph. Dessante, E. Odic, A. Simonin, H. P. L. de Esch, B. Lepetit, D. Alamarguy, F. Bayle, Ph. Teste
Format: Article
Language:English
Published: American Physical Society 2014-10-01
Series:Physical Review Special Topics. Accelerators and Beams
Online Access:http://doi.org/10.1103/PhysRevSTAB.17.103502
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spelling doaj-f011df0f7d51462e95cadad26098413e2020-11-25T00:35:56ZengAmerican Physical SocietyPhysical Review Special Topics. Accelerators and Beams1098-44022014-10-01171010350210.1103/PhysRevSTAB.17.103502Experimental study of the reduction of field emission by gas injection in vacuum for accelerator applicationsK. AlmaksourM. J. KirkpatrickPh. DessanteE. OdicA. SimoninH. P. L. de EschB. LepetitD. AlamarguyF. BaylePh. TesteField emission current from surfaces under vacuum and at high field strengths can be reduced by the injection of gas into the evacuated volume. In this paper, the effects of H_{2}, He, N_{2}, and Ar on this “dark” current emitted from a tungsten carbide point cathode for 2 cm gap distance is studied. Exposure to any of these gases at pressures on the order of 10^{−3}–10^{−2}  Pa was found to reduce the emission current by up to 90% with a time constant on the order of ∼1  minute as compared to the current at 10^{−6}  Pa. The effect was strongly dependent on the gas nature, with Ar and N_{2} having larger effects at lower pressures than He and H_{2}. The reduction was reversible, with the current increasing to near its original value with a time constant on the order of ∼1–10  minutes after pumping down. The effect of the gas remained in the absence of electric field, whatever the gas pressure. Mechanisms for these and related phenomena are discussed.http://doi.org/10.1103/PhysRevSTAB.17.103502
collection DOAJ
language English
format Article
sources DOAJ
author K. Almaksour
M. J. Kirkpatrick
Ph. Dessante
E. Odic
A. Simonin
H. P. L. de Esch
B. Lepetit
D. Alamarguy
F. Bayle
Ph. Teste
spellingShingle K. Almaksour
M. J. Kirkpatrick
Ph. Dessante
E. Odic
A. Simonin
H. P. L. de Esch
B. Lepetit
D. Alamarguy
F. Bayle
Ph. Teste
Experimental study of the reduction of field emission by gas injection in vacuum for accelerator applications
Physical Review Special Topics. Accelerators and Beams
author_facet K. Almaksour
M. J. Kirkpatrick
Ph. Dessante
E. Odic
A. Simonin
H. P. L. de Esch
B. Lepetit
D. Alamarguy
F. Bayle
Ph. Teste
author_sort K. Almaksour
title Experimental study of the reduction of field emission by gas injection in vacuum for accelerator applications
title_short Experimental study of the reduction of field emission by gas injection in vacuum for accelerator applications
title_full Experimental study of the reduction of field emission by gas injection in vacuum for accelerator applications
title_fullStr Experimental study of the reduction of field emission by gas injection in vacuum for accelerator applications
title_full_unstemmed Experimental study of the reduction of field emission by gas injection in vacuum for accelerator applications
title_sort experimental study of the reduction of field emission by gas injection in vacuum for accelerator applications
publisher American Physical Society
series Physical Review Special Topics. Accelerators and Beams
issn 1098-4402
publishDate 2014-10-01
description Field emission current from surfaces under vacuum and at high field strengths can be reduced by the injection of gas into the evacuated volume. In this paper, the effects of H_{2}, He, N_{2}, and Ar on this “dark” current emitted from a tungsten carbide point cathode for 2 cm gap distance is studied. Exposure to any of these gases at pressures on the order of 10^{−3}–10^{−2}  Pa was found to reduce the emission current by up to 90% with a time constant on the order of ∼1  minute as compared to the current at 10^{−6}  Pa. The effect was strongly dependent on the gas nature, with Ar and N_{2} having larger effects at lower pressures than He and H_{2}. The reduction was reversible, with the current increasing to near its original value with a time constant on the order of ∼1–10  minutes after pumping down. The effect of the gas remained in the absence of electric field, whatever the gas pressure. Mechanisms for these and related phenomena are discussed.
url http://doi.org/10.1103/PhysRevSTAB.17.103502
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