The Impact of Collisionality, FLR and Parallel Closure Effects on Instabilities in the Tomakak Pedestal: Numerical Studies with the NIMROD code

A. Y. Pankin; J. R. King; P. B. Snyder; S. E. Kruger

arxiv: 1702.00042 · v1 · pith:HXPHMVBHnew · submitted 2017-01-31 · ⚛️ physics.plasm-ph

The Impact of Collisionality, FLR and Parallel Closure Effects on Instabilities in the Tomakak Pedestal: Numerical Studies with the NIMROD code

J. R. King , A. Y. Pankin , S. E. Kruger , P. B. Snyder This is my paper

classification ⚛️ physics.plasm-ph

keywords nimrodcodeeffectsphysresistiveanalyticcalculationsclosure

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The extended-MHD NIMROD code [C.R. Sovinec and J.R. King, J. Comput. Phys. 229, 5803 (2010)] is verified against the ideal-MHD ELITE code [H.R. Wilson et al. Phys. Plasmas 9, 1277 (2002)] on a diverted tokamak discharge. When the NIMROD model complexity is increased incrementally, resistive and first-order finite-Larmour radius effects are destabilizing and stabilizing, respectively. The full result is compared to local analytic calculations which are found to overpredict both the resistive destabilization and drift stabilization in comparison to the NIMROD computations.

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The Impact of Collisionality, FLR and Parallel Closure Effects on Instabilities in the Tomakak Pedestal: Numerical Studies with the NIMROD code

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