Towards nonaxisymmetry; initial results using the Flux Coordinate Independent method in BOUT++

Shanahan, B.; Hill, P.; Dudson, B.

doi:10.1088/1742-6596/775/1/012012

Cited by 6 publications

(11 citation statements)

References 17 publications

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“…A Poincaré plot showing the flux surfaces calculated in Zoidberg is shown in figure 1. Figure 2 illustrates that simulating a parallel diffusion model qualitatively reveals the flux surfaces for a rotating ellipse equilibrium, recovering the results from [11,12]however this result differs in that it uses fully three dimensional metric tensor components, whereas the previous results utilized a metric tensor that varied in only two dimensions. It is perhaps worth mentioning that in initial testing the addition of variation in the third dimension has increased calculation time by about 5%-15%, so calculations do not require prohibitively more resources relative to conventional BOUT+ +simulations.…”

Section: Flux Surface Mapping Using Heat Diffusionsupporting

confidence: 52%

“…where b is the magnetic field vector. Here the diffusion model in equation (1) is used to test the numerical diffusion in a rotating ellipse equilibrium as done in [11,12]. Specifically, we will simulate this model on a rotating ellipse geometry.…”

Section: Flux Surface Mapping Using Heat Diffusionmentioning

confidence: 99%

“…The recent implementation of the flux coordinate independent (FCI) [10] method for parallel derivatives in BOUT+ +has allowed for simulations in non-axisymmetric geometries [11,12]. Instead of aligning the computational grid to magnetic field lines, the FCI method uses interpolation of field line mapping on poloidal (or, in the case of linear geometries, azimuthal) planes to obtain values for finite-difference differentiation parallel to the magnetic field.…”

Section: Introductionmentioning

confidence: 99%

“…Additionally, since the computational grid is no longer aligned to the magnetic field, the simulation of complex geometries including X-points is possible. For a more complete discussion of the FCI method, see [10][11][12].…”

Section: Introductionmentioning

confidence: 99%

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Fluid simulations of plasma filaments in stellarator geometries with BSTING

Shanahan

Dudson

Hill

2018

Plasma Phys. Control. Fusion

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Here we present first results simulating plasma filaments in non-axisymmetric geometries, using a fluid turbulence extension of the BOUT++ framework. This is made possible by the implementation of the Flux Coordinate Independent scheme for parallel derivatives, an extension of the metric tensor components which allows them to vary in three dimensions, and development of grid generation.Tests have been performed to confirm that the extension to three dimensional metric tensors does not compromise the accuracy and stability of the associated numerical operators. Recent changes to the FCI grid generator in BOUT++, including a curvilinear grid system which allows for potentially more efficient computation, are also presented. Initial simulations of seeded plasma filaments in a non-axisymmetric geometry are reported. We characterize filaments propagating in the closedfield-line region of a low-field-period, rotating ellipse equilibrium as inertially-limited by examining the velocity scaling and currents associated with the filament propagation. Finally, it is shown that filaments in a non-axisymmetric rotating ellipse equilibrium propagate in a toroidally nonuniform fashion, and it is determined that the long connection lengths in the scrape-off-layer enable parallel gradients to establish, which has consequences for interpretation of experimental data.

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Section: Flux Surface Mapping Using Heat Diffusionsupporting

confidence: 52%

Section: Flux Surface Mapping Using Heat Diffusionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Fluid simulations of plasma filaments in stellarator geometries with BSTING

Shanahan

Dudson

Hill

2018

Plasma Phys. Control. Fusion

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“…While BOUT++ is capable of simulating complex geometries [3][4][5], one can often explore complex phenomena by simplifying the problem. For this reason, isolated filament simulations in slab geometries are often employed [6][7][8].…”

Section: Introductionmentioning

confidence: 99%

The effects of non-uniform drive on plasma filaments

Shanahan

Dudson

Hill

2018

J. Phys.: Conf. Ser.

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Wendelstein 7-X core fueling is primarily achieved through pellet injection. The trajectory of plasmoids from an ablating pellet is an ongoing research question, which is complicated by the complex magnetic geometry of W7-X; curvature drive varies significantly toroidally, including a change in the drift drive direction. Here we use the Hermes model in BOUT++ to simulate cold plasma filaments in slab geometries where the magnetic drift drive is non-uniform along the field line. It is shown that if the field-line-averaged curvature drive is non-zero, a filament will propagate coherently in the direction of average drive. It is also shown that a non-uniform drive will provide a nonuniform propagation; an effect which is reduced at higher temperatures due to an increased sound speed along the field line. Finally, simulations with curvature similar to that found in Wendelstein 7-X are performed which indicate a slow radial propagation of plasma filaments despite a highly non-uniform drive profile.

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A partially mesh-free scheme for representing anisotropic spatial variations along field lines: Conservation, quadrature, and the delta property

Maloney

McMillan

2023

Computer Physics Communications

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Towards nonaxisymmetry; initial results using the Flux Coordinate Independent method in BOUT++

Cited by 6 publications

References 17 publications

Fluid simulations of plasma filaments in stellarator geometries with BSTING

Fluid simulations of plasma filaments in stellarator geometries with BSTING

The effects of non-uniform drive on plasma filaments

A partially mesh-free scheme for representing anisotropic spatial variations along field lines: Conservation, quadrature, and the delta property

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