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17–22 Oct 2016
Kyoto International Conference Center
Japan timezone

The role of the density profile location on pedestal stability in ASDEX Upgrade

19 Oct 2016, 15:20
20m
Kyoto International Conference Center

Kyoto International Conference Center

Takaragaike, Sakyo-ku, Kyoto 606-0001 Japan
Oral EXC - Magnetic Confinement Experiments: Confinement Pedestal & ELM Physics

Speaker

Dr Mike Dunne (IPP-Garching)

Description

Scrape-off layer (SOL) properties are controlled by a number of parameters, such as heating power, main ion fuelling, and impurity seeding. The high field side high density (HFSHD) is a region of high density (~10× higher than the separatrix density) localised to the HFS SOL and is observed in both ASDEX Upgrade (AUG) and JET when a gas puff at sufficient heating power is applied. It can be mitigated by either reducing the input power to the main plasma or by radiating this power, via, for example, nitrogen seeding, before it reaches the HFS SOL. Observations of the density profile and the HFSHD show that the presence of the HFSHD is linked with an outward shift of the density profile. Conversely, when it is mitigated, the profile shifts radially inwards. At the same time, nitrogen seeding has been observed to increase pedestal and global confinement in fuelled discharges on AUG by up to 40%. Interpretive pedestal modelling is used to validate the peeling-ballooning hypothesis of pedestal limiting ELM behaviour. While this is a valuable tool, it is limited since only final plasma states involving a variety of changes in impurity content, SOL characteristics, and global beta can be analysed. As such, a predictive pedestal tool (iPED) was developed using similar assumptions to the EPED model to vary each parameter independently. In addition to the standard inputs of predictive pedestal models, an ad-hoc shift of the density profile, based on experimental measurements, is included. An inward shift (of up to 0.01 rho_poloidal) has a dramatic impact on the predicted pedestal stability, increasing it by 30% in a typical AUG scenario and is the dominant factor determining the eventual pedestal top. Increased Z_eff and global beta also contribute to pedestal stabilisation, but have a smaller impact. To determine the final global plasma state, iPED is combined with the ASTRA transport model. ASTRA and iPED are iterated in a step-wise manner until convergence of the core and pedestal plasmas is reached. This allows the evolution of the global plasma in response to small changes at the separatrix to be modelled, and offers a demonstration of how SOL properties can impact both the pedestal and global confinement.
Country or International Organization Germany
Paper Number EX/3-5

Primary author

Dr Mike Dunne (IPP-Garching)

Co-authors

Dr Bernd Kurzan (IPP-Garching) Dr Elisabeth Wolfrum (Max Planck Institut fuer Plasmaphysik) Dr Emiliano Fable (IPP-Garching) Dr Felix Reimold (Forschungszentrum Jülich) Mr Florian Laggner (IAP Vienna) Dr Giovanni Tardini (IPP-Garching) Lorenzo Frassinetti (KTH, Royal Institute of Technology) Dr Marc Beurskens (CCFE) Mr Marco Cavedon (IPP-Garching/TUM Garching) Dr Marco Wischmeier (IPP Garching) Dr Matthias Bernert (IPP-Garching) Dr Matthias Willensdorfer (IPP Garching) Dr Rachael McDermott (Max Planck Institut für Plasmaphysik) Dr Rainer Fischer (IPP-Garching) Dr Steffen Potzel (IPP-Garching)

Presentation materials