An RF ion source model for H-production

A 1D model of an RF driven ion source based on ionisation by thermal electrons is presented. The RF source differs from traditional filament and arc ion sources because there are no primary electrons present, and is simply composed of an antenna region (driver) and a main plasma discharge region. Ho...

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Veröffentlicht in:	Plasma sources science & technology 2019-07, Vol.28 (7), p.75011
Hauptverfasser:	Turner, I, Holmes, A J T, Zacks, J, McAdams, R
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Sprache:	eng
Schlagworte:	fluid model negative ions RF ion source SNIF
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creator	Turner, I Holmes, A J T Zacks, J McAdams, R
description	A 1D model of an RF driven ion source based on ionisation by thermal electrons is presented. The RF source differs from traditional filament and arc ion sources because there are no primary electrons present, and is simply composed of an antenna region (driver) and a main plasma discharge region. However the model does still make use of the classical plasma transport equations for particle energy and flow, as used previously in DC source models where they have worked well. The model currently uses the geometry and other source parameters of the Small Negative Ion Facility (SNIF) ion source at CCFE and only considers the hydrogen ion species, but may be easily adapted to model other RF sources. The model provides a detailed description of the plasma parameters along the source axis, i.e. plasma temperature, density and potential, as well as current densities and species fluxes, but does not consider the RF matching unit. The inputs to the model are the source geometry, RF power, the magnetic filter field, the source gas pressure and the plasma grid insert bias. Results from the model are presented and where possible compared to existing experimental data from SNIF, with varying RF power, source pressure and insert bias.
doi_str_mv	10.1088/1361-6595/ab27db
format	Article
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The RF source differs from traditional filament and arc ion sources because there are no primary electrons present, and is simply composed of an antenna region (driver) and a main plasma discharge region. However the model does still make use of the classical plasma transport equations for particle energy and flow, as used previously in DC source models where they have worked well. The model currently uses the geometry and other source parameters of the Small Negative Ion Facility (SNIF) ion source at CCFE and only considers the hydrogen ion species, but may be easily adapted to model other RF sources. The model provides a detailed description of the plasma parameters along the source axis, i.e. plasma temperature, density and potential, as well as current densities and species fluxes, but does not consider the RF matching unit. The inputs to the model are the source geometry, RF power, the magnetic filter field, the source gas pressure and the plasma grid insert bias. 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Technol</addtitle><description>A 1D model of an RF driven ion source based on ionisation by thermal electrons is presented. The RF source differs from traditional filament and arc ion sources because there are no primary electrons present, and is simply composed of an antenna region (driver) and a main plasma discharge region. However the model does still make use of the classical plasma transport equations for particle energy and flow, as used previously in DC source models where they have worked well. The model currently uses the geometry and other source parameters of the Small Negative Ion Facility (SNIF) ion source at CCFE and only considers the hydrogen ion species, but may be easily adapted to model other RF sources. The model provides a detailed description of the plasma parameters along the source axis, i.e. plasma temperature, density and potential, as well as current densities and species fluxes, but does not consider the RF matching unit. The inputs to the model are the source geometry, RF power, the magnetic filter field, the source gas pressure and the plasma grid insert bias. 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The model provides a detailed description of the plasma parameters along the source axis, i.e. plasma temperature, density and potential, as well as current densities and species fluxes, but does not consider the RF matching unit. The inputs to the model are the source geometry, RF power, the magnetic filter field, the source gas pressure and the plasma grid insert bias. Results from the model are presented and where possible compared to existing experimental data from SNIF, with varying RF power, source pressure and insert bias.</abstract><pub>IOP Publishing</pub><doi>10.1088/1361-6595/ab27db</doi><tpages>15</tpages><orcidid>https://orcid.org/0000-0003-1487-3171</orcidid></addata></record>
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subjects	fluid model negative ions RF ion source SNIF
title	An RF ion source model for H-production
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