Dual view FIDA measurements on MAST

TL;DR

This paper presents the implementation and analysis of a FIDA spectrometer on MAST, revealing insights into fast ion behavior, mode effects, and transport mechanisms through experimental measurements and theoretical comparisons.

Contribution

The study introduces dual view FIDA measurements on MAST, providing detailed diagnostics of fast ion distributions and their transport under various plasma conditions, with comparisons to theoretical models.

Findings

FIDA signals agree with classical simulations in quiescent discharges.

Mode activity significantly reduces core FIDA signals, indicating enhanced transport.

Vertical and toroidal views reveal different behaviors near the trapped-passing boundary.

Abstract

A Fast Ion Deuterium Alpha (FIDA) spectrometer was installed on MAST to measure radially resolved information about the fast ion density and its distribution in energy and pitch angle. Toroidally and vertically-directed collection lenses are employed, to detect both passing and trapped particle dynamics, and reference views are installed to subtract the background. This background is found to contain a substantial amount of passive FIDA emission driven by edge neutrals, and to depend delicately on viewing geometry. Results are compared with theoretical expectations based on the codes NUBEAM (for fast ion distributions) and FIDASIM. Calibrating via the measured beam emission peaks, the toroidal FIDA signal profile agrees with classical simulations in MHD quiescent discharges where the neutron rate is also classical. Long-lived modes (LLM) and chirping modes decrease the core FIDA signal significantly, and the profile can be matched closely to simulations using anomalous diffusive transport; a spatially uniform diffusion coefficient is sufficient for chirping modes, while a core localized diffusion is better for a LLM. Analysis of a discharge with chirping mode activity shows a dramatic drop in the core FIDA signal and rapid increase in the edge passive signal at the onset of the burst indicating a very rapid redistribution towards the edge. Vertical viewing measurements show a discrepancy with simulations at higher Doppler shifts when the neutron rate is classical, which, combined with the fact that the toroidal signals agree, means that the difference must be occurring for pitch angles near the trapped-passing boundary. Further evidence of an anomalous transport mechanism for these particles is provided by the fact that an increase of beam power does not increase the higher energy vertical FIDA signals, while the toroidal signals do increase.