Samenvatting
Results on key aspects of scrape-off layer (SOL) heat transport and
divertor power load associated with pellet-induced edge localized modes
(ELMs) in comparison with spontaneous ELMs are presented. We focus on
the 3D structure of the SOL heat transport by revealing the footprints
of power load on the divertor target. Additionally, the time scales of
ELM loss and consecutive energy transport in the SOL toward the divertor
target of pellet-induced ELMs are discussed.
By employing a toroidal magnetic field (BT) scan we achieve
evidence that a toroidally asymmetric divertor power deposition
structure is extending to positions exceptionally far off the strike
line and exceeding toroidally localized the power flux density at the
strike line. Field line tracing is used to predict correctly for the
full BT scan the position of the divertor power footprint of
an ELM filament through the pellet injection trajectory. Consistently
the divertor heat flux modeled with the non-linear MHD-code JOREK
features in addition to the toroidally symmetric component peaking at
the strike line a spiral-like structure joining this symmetric component
from higher radii. For the investigated JET discharges we conclude that
the divertor heat loads due to pellet-induced ELM consist of two
components. First, the toroidally symmetric peak heat load at the strike
line is comparable to the one of spontaneous ELMs. Secondly, the
toroidal asymmetric component is found to be higher by ~30% at a
toroidal position defined by the SOL field line pitch.
Originele taal-2 | Engels |
---|---|
Pagina's (van-tot) | 105002 |
Tijdschrift | Plasma Physics and Controlled Fusion |
Volume | 53 |
Nummer van het tijdschrift | 10 |
DOI's | |
Status | Gepubliceerd - 1 okt. 2011 |
Extern gepubliceerd | Ja |