2021
DOI: 10.1063/5.0042498
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A review of diagnostic techniques for high-intensity negative ion sources

Abstract: Plasma and beam diagnostic methods for high-current-density negative ion sources are reviewed. The pulse laser–induced photodetachment method was widely used to measure negative ion density in the ion source plasma. The method was used to understand fundamental processes of negative hydrogen (H−) ion formation and destruction in hydrogen plasmas. Species composition and plasma parameters in H− ion sources can be estimated from optical emission spectroscopy data, while electrostatic probes are utilized to obtai… Show more

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Cited by 20 publications
(22 citation statements)
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“…The CRDS diagnostic was used to characterize and maximize the availability of negative ions at the PG, as a function of the source operation parameters. The volume production of negative ions grows with the plasma density, which in turn grows with the input power used to sustain the plasma [ [5], [6], [10]]. Figure 3a shows how the Hdensity grows as a function of total RF power, each RF generator providing 1/4 of the total.…”
Section: Source Experimental Resultsmentioning
confidence: 99%
See 1 more Smart Citation
“…The CRDS diagnostic was used to characterize and maximize the availability of negative ions at the PG, as a function of the source operation parameters. The volume production of negative ions grows with the plasma density, which in turn grows with the input power used to sustain the plasma [ [5], [6], [10]]. Figure 3a shows how the Hdensity grows as a function of total RF power, each RF generator providing 1/4 of the total.…”
Section: Source Experimental Resultsmentioning
confidence: 99%
“…This is possible thanks to the Cavity Ring-Down Spectroscopy (CRDS) [7] diagnostic installed in SPIDER [ [8], [9]], which provides Line-of-Sight (LoS) integrated measurements of H -/Ddensity in proximity of the ion extraction apertures. This technique has been successfully applied to other several negative ion sources for fusion applications [ [6], [10]- [17]]. The CRDS diagnostic in SPIDER can provide H -/Ddensity measurements at 10 Hz rate, with a minimum detection threshold of few 10 15 m -3 .…”
Section: Introductionmentioning
confidence: 99%
“…4. The density fluctuation in the vicinity of the PG is measured by a Langmuir probe (LP) [7]. The location of the probe measurement is 12 mm from the PG, and at the almost center of the aperture, where the presheath is formed when the extraction voltage is applied to the second grid (extraction grid).…”
Section: Methodsmentioning
confidence: 99%
“…To counteract the co-extraction of electrons, magnets embedded in the EG produce alternated vertical magnetic fields that dump the co-extracted electrons onto the EG surface, while causing minimal deviations of the negative ion trajectories [1]. Furthermore, the amount of electrons in the proximity of the PG apertures is reduced in two ways; first, a current IPG flows vertically in the PG, generating a magnetic filter field (1.6 mT close to the PG per 1 kA of current) that locally reduces density and energy of electrons [ [1], [5], [10], [20]]. Second, the plasma potentials can be modified by making currents flow between different electric components of the source [ [5], [10], [20]- [22]].…”
Section: The Spider Ion Sourcementioning
confidence: 99%