Plasma turbulence simulations with X-points using the flux-coordinate independent approach

In this work, the flux-coordinate independent (FCI) approach to plasma turbulence simulations is formulated for the case of generic, static magnetic fields, including those possessing stochastic field lines. It is then demonstrated that FCI is applicable to nonlinear turbulent problems with and without X-point geometry. In particular, by means of simulations with the FENICIA code, it is shown that the standard features of ion temperature gradient (ITG) modes are recovered with reduced toroidal resolution. Finally, the impact of ITG turbulent transport on the temperature profile is studied under the influence of a static island, with ITER-like parameters. Results show the wide range of applicability of the method.

Plasma turbulence simulations with X-points using the flux-coordinate independent approach

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Iterative removal of sources to model the turbulent electromotive force

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Iterative removal of sources to model the turbulent electromotive force

Teacher-Mediated and Student-Led Interaction with a Physics Simulation: Effects on the Learning Experience

Spatial Modeling for Building Design Evaluation: from Visual Landscape Quality Assessment to Devaluation Risk Estimation