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Return To: Session TH1 - Theory 1 (Tuesday, 20 October)
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B. Scott , F. Jenko , A. Peeters ,
A. C-Y. Teo
Max Planck Institut für Plasmaphysik, Euratom Association,
D-85748 Garching bei München, Germany
Abstract
(1) Computations of turbulence from the electromagnetic gyrofluid
model are performed in a flux surface geometry representing the actual MHD
equilibrium of the ASDEX Upgrade edge flux surfaces. The transition to ideal
ballooning seen in simple geometries as the plasma beta rises is suppressed,
leaving the transport at quantitatively realistic levels. Computations for
core parameters at half-radius geometry show significant contribution due to
the finite beta electron dynamics, possibly removing the standard ITG
threshold. (2) Strong inward vorticity transport in edge turbulence, resulting
from ion diamagnetic flows, may lead to a build up of mean ExB vorticity fast
enough to cause an H-mode transition. (3) Friction of mean ion flows against
neutrals involves both toroidal and poloidal flow components, leading to a
finite radial current due to a given ExB profile even with zero poloidal
rotation.
IAEA 1999