R. Schneider , D. P. Coster , A. Kallenbach ,
K. Borrass , H.-S. Bosch , J. C. Fuchs , J. Gafert ,
A. Herrmann , V. Mertens , J. Neuhauser , J. Schweinzer ,
U. Wenzel , B. Braams 1, D. Reiter 2, and the
ASDEX Upgrade Team
Max-Planck-Institut für Plasmaphysik, EURATOM Association,
D-85748 Garching
1 Courant Institute, New York University, New York, NY 10012
2 IPP, Forschungszentrum Jülich GmbH, EURATOM Association, D-52425
Jülich
Abstract
Based on validated B2-Eirene results for the previous divertor of
ASDEX Upgrade , the modelling predictions for the new divertor are compared
with the actual experimental results. For the same experimental scenarios
(L-mode ) in both divertors the predictions are robust and in agreement with
experimental results. For a full quantative agreement in H-mode both the
carbon chemical sputtering yield and the radial transport had to be
adjusted. The new divertor has a reduced power load due to larger radiation
losses. These are caused by larger hydrogen losses, enhancement of carbon
radiation due to radial transport and convective energy transport into the
radiation zone, and larger radial energy transport in the divertor.
IAEA 1999