The high field side high density region in SOLPS-modeling of nitrogen-seeded H-modes in ASDEX Upgrade

The high field side high density region in SOLPS-modeling of nitrogen-seeded H-modes in ASDEX Upgrade

The understanding of divertor physics and the evolution of divertor detachment is crucial for developing the capability to model power exhaust in current experiments and reliably predict it for future fusion devices. In simulations of ASDEX Upgrade, an experimentally observed region of high density...

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Bibliographic Details
Published in:Nuclear materials and energy Vol. 12; pp. 193 - 199
Main Authors: Reimold, F., Wischmeier, M., Potzel, S., Guimarais, L., Reiter, D., Bernert, M., Dunne, M., Lunt, T.
Format: Journal Article
Language:English
Published: Elsevier Ltd 01-08-2017
Elsevier
Subjects:
ASDEX-Upgrade
Detachment
Divertor plasma
High field side high density
PSI-21: Edge modeling
SOLPS
ASDEX-Upgrade
High field side high density
Detachment
PSI-21: Edge modeling
Divertor plasma
SOLPS
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Summary:The understanding of divertor physics and the evolution of divertor detachment is crucial for developing the capability to model power exhaust in current experiments and reliably predict it for future fusion devices. In simulations of ASDEX Upgrade, an experimentally observed region of high density in the high field side scrape-off layer has been recovered. Validated modeling with SOLPS5.0 shows that a detailed match of the high field side scrape-off layer plasma is not only important for local plasma parameters, but can lead to strong changes in global parameters. Drifts play a crucial role in lower-single null discharges with forward toroidal field (∇B→-drift pointing down). Their inclusion changes the spatial extent as well as the radial and poloidal gradients of the high field side high density. Adapted transport coefficients that take into account core fueling by plasma diffusion due to the presence of the high field side density and drift-driven radial fluxes now reconcile the modeled deuterium compression ratio, divertor neutral density, neutral radiation levels and deuterium fueling rates with experimental measurements. The onset of strong volume recombination in the simulations now allows to remove the previously necessary increase of perpendicular transport in the inner divertor from the simulations.
ISSN:2352-1791
2352-1791
DOI:10.1016/j.nme.2017.01.010