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dc.contributor.authorNoguera, Virginia R.
dc.contributor.authorBlantocas, Gene Q.
dc.contributor.authorRamos, Henry J.
dc.date.accessioned2024-04-27T07:12:38Z
dc.date.available2024-04-27T07:12:38Z
dc.date.issued2008-06
dc.identifier.citationNoguera, V. R., Blantocas, G. Q., & Ramos, H. J. (2008). Optimized H−extraction in an argon–magnesium seeded magnetized sheet plasma. Nuclear Instruments and Methods in Physics Research Section B: Beam Interactions with Materials and Atoms, 266(11), 2627-2637. https://doi.org/10.1016/j.nimb.2008.01.037en
dc.identifier.issn0168-583X
dc.identifier.urihttps://hdl.handle.net/20.500.14353/377
dc.description.abstractThe enhancement and optimization of H− extraction through argon and magnesium seeding of hydrogen discharges in a magnetized sheet plasma source are reported. The paper first presents the modification of the production chamber into a hexapole multicusp configuration resulting in decreased power requirements, improved plasma confinement and longer filament lifetime. By this, a wider choice of discharge currents for sustained quiescent plasmas is made possible. Second, the method of adding argon to the hydrogen plasma similar to the scheme in Abate and Ramos [Y. Abate, H. Ramos, Rev. Sci. Instr. 71 (10) (2000) 3689] was performed to find the optimum conditions for H− formation and extraction. Using an E×B probe, H− yields were investigated at varied argon–hydrogen admixtures, different discharge currents and spatial points relative to the core plasma. The optimum H− current density extracted at 3.0cm from the plasma core using 3.0 A plasma current with 10% argon seeding increased by a factor of 2.42 (0.63A/m2) compared to the measurement of Abate and Ramos [Y. Abate, H. Ramos, Rev. Sci. Instr. 71 (10) (2000) 3689]. Third, the argon–hydrogen plasma at the extraction chamber is seeded with magnesium. Mg disk with an effective area of 22cm2 is placed at the extraction region’s anode biased 175V with respect to the cathode. With Mg seeding, the optimum H− current density at the same site and discharge conditions increased by 4.9 times (3.09A/m2). The enhancement effects were analyzed vis-à-vis information gathered from the usual Langmuir probe (electron temperature and density), electron energy distribution function (EEDF) and the ensuing dissociative attachment (DA) reaction rates at different spatial points for various plasma discharges and gas ratios. Investigations on the changes in the effective electron temperature and electron density indicate that the enhancement is due to increased density of low-energy electrons in the volume, conducive for DA reactions. With Mg, the density of electrons with electron temperature of about 3eV increased 3 orders of magnitude from 2.76×1012m−3 to 2.90×1015m−3.en
dc.language.isoenen
dc.publisherElsevier B.V.en
dc.subjectMagnetized sheet plasmaen
dc.subjectRovibrational excitationen
dc.subjectDissociative attachmenten
dc.subjectAtomic processesen
dc.subjectMolecular processesen
dc.subjectHydrogen anionen
dc.subjectHydrogen moleculesen
dc.subjectElectron impacten
dc.subjectElectron energy distribution functionen
dc.subjectH− productionen
dc.subjectStreaming neutral gas injectionen
dc.subject.lcshPlasma (Ionized gases)en
dc.subject.lcshArgonen
dc.subject.lcshHydrogenen
dc.subject.lcshAtomic hydrogenen
dc.subject.meshHydrogenen
dc.subject.meshElectronsen
dc.subject.meshPlasma Gasesen
dc.titleOptimized H− extraction in an argon–magnesium seeded magnetized sheet plasmaen
dc.typeArticleen
dcterms.accessRightsLimited public accessen
dc.citation.journaltitleNuclear Instruments and Methods in Physics Research Section B: Beam Interactions with Materials and Atomsen
dc.citation.volume266en
dc.citation.issue11en
dc.citation.firstpage2627en
dc.citation.lastpage2637en
dc.identifier.doi10.1016/j.nimb.2008.01.037
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local.isIndexedByScopusen


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