TY - JOUR
T1 - Fast response, optical radiance measurements of low intensity impurity emission in WEST plasmas with staggered wavelength filters
AU - Neff, A. L.
AU - Unterberg, E. A.
AU - Klepper, C. C.
AU - Meyer, O.
AU - Davda, K.
AU - Fehling, D. T.
AU - Pascal, J. Y.
AU - Harris, J. H.
N1 - Publisher Copyright:
© 2020 IOP Publishing Ltd and Sissa Media lab.
PY - 2020/2
Y1 - 2020/2
N2 - Fast response acquisition of atomic line emission through the use of a filter scope has been implemented on the WEST tokamak at multiple poloidal locations. Filter scopes consist of a fiber-optic-based transmission from the tokamak to specifically engineered optical band passes and photomultiplier tubes (PMT) that collect the emission intensity to measure a radiance, L [W/cm2/str], over the specified bandpass. This diagnostic records plasma-wall interaction (PWI) properties (e.g. impurity emission and recycling of main fuel ions) up to a max acquisition rate of 100 kHz. These PMT radiometric measurements are calibrated into a line-normalized radiance, LN [photons/sec/cm2/str], similar to traditional spectrometers, which can later be converted to a particle flux. Low intensity emission peaks are difficult to quantify due to often comparable continuum levels, thus a secondary filter shifted to a judiciously-selected, line-free region (∼1 nm away) allows for background subtraction. The system currently installed on WEST targets tungsten (W) gross sputtering specifically by monitoring, with a filter pair, the spectral region near the neutral W line emission (W I 400.9 nm). The line and background filters of the pair are centered at 400.6 nm and 403.1 nm, respectively. Through a set beam splitters on each sight line, the filter pair are measuring from the same location. The two L signals near W I are then subtracted from each other yielding only the W I LN. W I LN data from a recent WEST experimental campaign is presented and compared with plasma parameters and traditional spectrometer measurements of W I line emission to demonstrate the capabilities of this staggered-filter filterscope method. Specifically, the choice of WEST-specific bandpass curves for the W I LN will be illustrated based on this latter comparison.
AB - Fast response acquisition of atomic line emission through the use of a filter scope has been implemented on the WEST tokamak at multiple poloidal locations. Filter scopes consist of a fiber-optic-based transmission from the tokamak to specifically engineered optical band passes and photomultiplier tubes (PMT) that collect the emission intensity to measure a radiance, L [W/cm2/str], over the specified bandpass. This diagnostic records plasma-wall interaction (PWI) properties (e.g. impurity emission and recycling of main fuel ions) up to a max acquisition rate of 100 kHz. These PMT radiometric measurements are calibrated into a line-normalized radiance, LN [photons/sec/cm2/str], similar to traditional spectrometers, which can later be converted to a particle flux. Low intensity emission peaks are difficult to quantify due to often comparable continuum levels, thus a secondary filter shifted to a judiciously-selected, line-free region (∼1 nm away) allows for background subtraction. The system currently installed on WEST targets tungsten (W) gross sputtering specifically by monitoring, with a filter pair, the spectral region near the neutral W line emission (W I 400.9 nm). The line and background filters of the pair are centered at 400.6 nm and 403.1 nm, respectively. Through a set beam splitters on each sight line, the filter pair are measuring from the same location. The two L signals near W I are then subtracted from each other yielding only the W I LN. W I LN data from a recent WEST experimental campaign is presented and compared with plasma parameters and traditional spectrometer measurements of W I line emission to demonstrate the capabilities of this staggered-filter filterscope method. Specifically, the choice of WEST-specific bandpass curves for the W I LN will be illustrated based on this latter comparison.
KW - Detector alignment
KW - Photon detectors for uv
KW - Plasma diagnostics a- interferometry
KW - calibration methods (lasers, sources, particle-beams)
KW - ir photons (solid-state)
KW - spectroscopy imaging
KW - visible
UR - http://www.scopus.com/inward/record.url?scp=85091337935&partnerID=8YFLogxK
U2 - 10.1088/1748-0221/15/02/C02045
DO - 10.1088/1748-0221/15/02/C02045
M3 - Article
AN - SCOPUS:85091337935
SN - 1748-0221
VL - 15
JO - Journal of Instrumentation
JF - Journal of Instrumentation
IS - 2
M1 - C02045
ER -