Abstract
With the objective of understanding the energetic-particle loss mechanism in three-dimensional plasmas, a Faraday-cup-based fast-ion loss detector (FILD) was developed and installed in OP1.2b in Wendelstein 7-X (W7-X) as a collaboration between the National Institute for Fusion Science and Max-Planck-Institute for Plasma Physics. The FILD, which consists of double apertures and thin aluminum foils, was based on a magnetic spectrometer using the magnetic field of the fusion device. The double aperture limits the thermal ion, but allows the energetic ion to enter the FILD box. The thin aluminum foils serve as the ion collector. Orbit-following calculations were performed in order to find a suitable position for the FILD. The results indicated that barely co- and counter-going transit ions reached the FILD position mounted on the multi-purpose manipulator installed on W7-X. Moreover, because the injection angle of neutral beams injector installed on W7-X was relatively perpendicular, the target range of pitch angle was set to from 91 degrees to 150 degrees. An energy-and-pitch-angle map was created using a grid calculation code in order to decide on the position/size of aperture and aluminum foil. The grid calculation code indicates the position where the energetic ion would strike on the aluminum foil. Here, the map was used as the basis for designing an aluminum foil pattern with two energies and four pitch angle ranges. Also, note that the lower energy range was designed so that it accommodates a neutral beam injection energy of 55 kV. Measurements of beam ion losses were performed in neutral beam (NB) blip experiments, where concurrent increases and decreases of barely co-going transit beam ion losses due to NB injections were observed. Furthermore, this study validated that the FILD installed on a midplane manipulator probe is capable of probing a range of radii spanning 1.0–1.5 cm, over which the beam ion loss current would vary significantly.
Highlights
The grid calculation code indicates the position where the energetic ion would strike on the aluminum foil
Poincaré plot (c) of co-going transit beam ion orbit reaching the fast-ion loss detector (FILD) calculated by the Lorentz orbit code (LORBIT) code
Initial results of orbit-following simulations using experimental data by ASCOT code showed that the signal synchronized with short neutral beam (NB) injection was observed in S1 and S2 [18]
Summary
The FILD head designed for W7-X appears in Fig. 3(a), with outer radius and head length of approximately 80 and 92 mm, respectively. Electrical current from each Faraday film is carried to the low-input impedance current amplifier (I-76, NF Corporation, a gain of 104 V/A). Note that the amplitude of alternating current noise having frequency of 50 Hz in each channel was largely suppressed after the 9-V battery was applied for the current amplifier. The authors found that the main components of noise were contaminated between the Faraday films and the input cable of the current amplifier. To date, they had no methods for determining how the noise could be avoided.
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