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(THP2/04) Edge and Coupled Core/Edge Transport Modelling in Tokamaks

L. L. Lodestro, T. A. Casper, R. H. Cohen, N. Mattor, L. D. Pearlstein, G. D. Porter, M. Rensink, T. Rognlien, D. D. Ryutov, H. A. Scott, and A. S. Wan

Lawrence Livermore National Laboratory P. O. Box 808, Livermore, CA 94551, USA

Abstract.  Recent advances in the theory and modelling of tokamak edge, scrape-off-layer (SOL) and divertor plasmas are described. The effects of the poloidal E×B drift on inner/outer divertor-plate asymmetries within a 1D analysis are shown to be in good agreement with experimental trends; above a critical v E×B, the model predicts transitions to supersonic SOL flow at the inboard midplane. 2D simulations show the importance of E×B flow in the private-flux region and of $\nabla$B-drifts. A theory of rough plasma-facing surfaces is given, predicting modifications to the SOL plasma. The parametric dependence of detached-plasma states in slab geometry has been explored; with suffcient pumping, the location of the ionization front can be controlled; otherwise only fronts near the plate or the X-point are stable. Studies with a more accurate Monte-Carlo neutrals model and a detailed non-LTE radiation-transport code indicate various effects are important for quantitative modelling. Detailed simulations of the DIII-D core and edge are presented; impurity and plasma flow are discussed and shown to be well modelled with UEDGE.

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