TY  - JOUR
AU  - Zhao, D.
AU  - Yi, R.
AU  - Eksaeva, A.
AU  - Oelmann, J.
AU  - Brezinsek, S.
AU  - Sergienko, G.
AU  - Rasinski, M.
AU  - Gao, Y.
AU  - Mayer, M.
AU  - Dhard, C. P.
AU  - Naujoks, D.
AU  - Cai, L.
TI  - Quantification of erosion pattern using picosecond-LIBS on a vertical divertor target element exposed in W7-X
JO  - Nuclear fusion
VL  - 61
IS  - 1
SN  - 1741-4326
CY  - Vienna
PB  - IAEA
M1  - FZJ-2021-01467
SP  - 016025 -
PY  - 2021
AB  - A set of dedicated marker samples consisting of fine-grain graphite as substrate, an interlayer of 0.2–0.4 μm molybdenum (Mo) employed as marker, and a 5–10 μm thick carbon (C) marker layer on top were installed in Wendelstein 7-X (W7-X) to investigate locally the C erosion and deposition. In this study, a set of five individual marker tiles, installed in a vertical divertor element of the test divertor unit in half-module 50, and exposed to about 40 min of plasma predominant in the standard magnetic divertor configuration in the first year of divertor operation in W7-X (OP1.2A), were retrieved from the vessel for post-mortem analysis. Picosecond laser induced breakdown spectroscopy (ps-LIBS) was applied on these marker tiles in order to determine the local erosion/deposition pattern caused by plasma impact. The general erosion/deposition pattern on the vertical target element was studied with the aid of depth-profiling by Mo line emission due to ps-LIBS with the number of applied laser pulses (355 nm, 2.3 J cm−2, 35 ps) at one probing location. Several potential asymmetry factors which avoid a perfect layer-by-layer ablation process in the laser ablations are proposed and discussed when a rough layered structure sample with a rough surface is analysed by the ps-LIBS technique. Thereby, a simulation model was developed to correct the measurement error of the ps-LIBS method caused by the non-perfect rectangle profile of the applied laser beam. The depth resolution of the applied ps-LIBS system was determined by quantification of the laser ablation rates of the different layers and the C substrate which were measured utilising profilometry and cross comparison with the thicknesses of the C and Mo marker layers determined by a combined focused ion beam and scanning electron microscopy technique. For the first time, the erosion/deposition pattern on the vertical target was mapped and quantified by ps-LIBS technique. A relatively wide net erosion zone with a poloidal extend of about 200 mm was identified which can be correlated to the main particle interaction zone at the magnetic strike-line of the dominantly applied standard magnetic divertor configuration. At the position of peak erosion, not only 7.6 × 1019 C atoms/cm2 but also 2 × 1018 Mo atoms/cm2 which results can be extrapolated to total 15 × 1019 C atoms/cm2, were eroded due to plasma fuel particle (H, He) and impurity (O, C) ion impact.
LB  - PUB:(DE-HGF)16
UR  - <Go to ISI:>//WOS:000598062900001
DO  - DOI:10.1088/1741-4326/abc408
UR  - https://juser.fz-juelich.de/record/891378
ER  -