Alternative RF coupling configurations for H− ion sources

Briefi, S.; Gutmann, P.; Fantz, U.

doi:10.1063/1.4916445

Cited by 11 publications

(15 citation statements)

References 15 publications

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“…The standard helicon wave coupling usually requires magnetic field strengths up to 100 mT which might not be feasible to accommodate for in a DEMO source concept. In the present configuration, the low-field peak is observed at magnetic field strengths of 2 -4 mT for hydrogen and deuterium depending on the pressure [30,32].…”

Section: Rf-efficiency and Reliabilitymentioning

confidence: 60%

Towards powerful negative ion beams at the test facility ELISE for the ITER and DEMO NBI systems

et al. 2017

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The test facility ELISE represents an important step in the European R&D roadmap towards the neutral beam injection (NBI) systems at ITER. ELISE provides early experience with operation of large radio frequency (RF) driven negative hydrogen ion sources. Starting with first plasma pulses in March 2013, ELISE has meanwhile demonstrated stable 1 h plasma discharges with repetitive 10 s beam extraction pulses every 3 min in hydrogen and deuterium at the ITER required pressure of 0.3 Pa. Stable ion currents of 9.3 A and 5.8 A have been extracted using only one quarter of the available RF power and reducing the extraction voltage in order to control the co-extracted electrons. The best hydrogen pulse for the required 1000 s for hydrogen gave an extracted current of 21.4 A and resulted in an accelerated current of 17.9 A, using only 53 kW per driver. Linear scaling towards full RF power (90 kW/driver) predicts that the target value of the negative ion current (H‾: 33 A extracted, 23 A accelerated; D‾: 28 A extracted and 20 A accelerated) can be achieved or even exceeded. Issues in long pulse operation are the caesium dynamics and the stability of the co-extracted electron current, for which the caesium management and the magnetic field configuration are promising tools for optimisation. Operation at high RF power for long pulses has highest priority for the next experimental campaign. In parallel or in a later stage, ELISE could serve as a test bed for studies on a DEMO NBI system. Examples are concepts concerning RF efficiency, operation with largely reduced caesium consumption or with caesium alternatives, and neutralization of the accelerated ion beam by a laser neutralizer in order to improve efficiency and reliability of NBI systems. Lab scale experiments on these topics are carried out presently in parallel with ELISE operation.

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Section: Rf-efficiency and Reliabilitymentioning

confidence: 60%

Towards powerful negative ion beams at the test facility ELISE for the ITER and DEMO NBI systems

et al. 2017

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“…The laboratory experiment CHARLIE (Concept studies for Helicon Assisted RF Low pressure Ion sourcEs) is actually intended to investigate the possibility of applying Helicon coupling for RF driven H − ion sources [17,18]. However, during the benchmark measurement campaign for the NINJA code, the experiment was operated as ICP using a helical coil made out of copper tube (6 mm diameter) with 5 windings.…”

Section: Charliementioning

confidence: 99%

Experimental benchmark of the NINJA code for application to the Linac4 H⁻ion source plasma

et al. 2017

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“…As shown in the schematic block diagram in Fig. 5, the AC system is implemented at a well characterized ICP experiment 38 consisting of a cylindrical stainless steel vacuum vessel with 15 cm in diameter and 10 cm in height. A water cooled planar RF antenna with seven windings is used, which is located in an evacuated chamber on top of the vessel and separated from the plasma chamber by a 3 mm thin dielectric quartz plate.…”

Section: B Icp Experimentsmentioning

confidence: 99%

Application of a Langmuir probe AC technique for reliable access to the low energy range of electron energy distribution functions in low pressure plasmas

Heiler

Friedl

Fantz

2020

Journal of Applied Physics

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The electron energy distribution function (EEDF) in low pressure plasmas is typically evaluated by using the second derivative d 2 I/dV 2 of a Langmuir probe I-V characteristic (Druyvesteyn formula). Since measured probe characteristics are inherently noisy, two-time numerical differentiation requires data smoothing techniques. This leads to a dependence on the employed filtering technique and information particularly in the region near the plasma potential can easily get lost. As an alternative to numerical differentiation of noisy probe data, a well-known AC probe technique is adopted to measure d 2 I/dV 2 directly. This is done by superimposing a sinusoidal AC voltage of 13 kHz on the probe DC bias and performing a Fourier analysis of the current response. Parameters like the modulation amplitude (up to 1.5 V) and number of applied sine oscillations per voltage step of the DC ramp are carefully chosen by systematic parameter variations. The AC system is successfully benchmarked in argon and applied to hydrogen plasmas at a laboratory ICP experiment (4 − 10 Pa gas pressure, 300 − 1000 W RF power). It is shown that the EEDF is reliably accessible with high accuracy and stability in the low energy range. Hence, a trustworthy determination of basic plasma parameters by integration of the EEDF can be provided.

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Alternative RF coupling configurations for H− ion sources

Cited by 11 publications

References 15 publications

Towards powerful negative ion beams at the test facility ELISE for the ITER and DEMO NBI systems

Towards powerful negative ion beams at the test facility ELISE for the ITER and DEMO NBI systems

Experimental benchmark of the NINJA code for application to the Linac4 H⁻ion source plasma

Application of a Langmuir probe AC technique for reliable access to the low energy range of electron energy distribution functions in low pressure plasmas

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Alternative RF coupling configurations for H− ion sources

Cited by 11 publications

References 15 publications

Towards powerful negative ion beams at the test facility ELISE for the ITER and DEMO NBI systems

Towards powerful negative ion beams at the test facility ELISE for the ITER and DEMO NBI systems

Experimental benchmark of the NINJA code for application to the Linac4 H−ion source plasma

Application of a Langmuir probe AC technique for reliable access to the low energy range of electron energy distribution functions in low pressure plasmas

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Experimental benchmark of the NINJA code for application to the Linac4 H⁻ion source plasma