Penalization technique to model wall-component impact on heat and mass transport in the tokamak edge

A. Paredes; H. Bufferand; F. Schwander; G. Ciraolo; E. Serre; Ph Ghendrih; P. Tamain

doi:10.1016/j.jnucmat.2013.01.131

Penalization technique to model wall-component impact on heat and mass transport in the tokamak edge

A. Paredes, H. Bufferand, F. Schwander, G. Ciraolo, E. Serre, Ph Ghendrih, P. Tamain

Resultado de la investigación: Contribución a una revista › Artículo › revisión exhaustiva

11 Citas (Scopus)

Resumen

The original and computationally efficient volume penalization technique Ref. [1], proposed for an isothermal plasma to recover the Bohm boundary condition at the plasma-obstacle interface, is extended to model 3D obstacles. It is then generalized to handle electron and ion temperatures in a 1D model. Results in 3D simulations show that the geometry of secondary limiter has an influence on the density and particle flux profiles, breaking its toroidal symmetry and introducing profile gaps of magnitude of 20%. On the other hand, the generalization of the penalization scheme to the non-isothermal case demands to deal with new Neumann conditions on the heat fluxes. Those boundary conditions require the introduction of new mask functions to ensure that the Bohm boundary condition remains satisfied.

Idioma original	Inglés
Páginas (desde-hasta)	S625-S628
Publicación	Journal of Nuclear Materials
Volumen	438
N.º	SUPPL
DOI	https://doi.org/10.1016/j.jnucmat.2013.01.131
Estado	Publicada - 2013
Publicado de forma externa	Sí

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abstract = "The original and computationally efficient volume penalization technique Ref. [1], proposed for an isothermal plasma to recover the Bohm boundary condition at the plasma-obstacle interface, is extended to model 3D obstacles. It is then generalized to handle electron and ion temperatures in a 1D model. Results in 3D simulations show that the geometry of secondary limiter has an influence on the density and particle flux profiles, breaking its toroidal symmetry and introducing profile gaps of magnitude of 20%. On the other hand, the generalization of the penalization scheme to the non-isothermal case demands to deal with new Neumann conditions on the heat fluxes. Those boundary conditions require the introduction of new mask functions to ensure that the Bohm boundary condition remains satisfied.",

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T1 - Penalization technique to model wall-component impact on heat and mass transport in the tokamak edge

AU - Paredes, A.

AU - Bufferand, H.

AU - Schwander, F.

AU - Ciraolo, G.

AU - Serre, E.

AU - Ghendrih, Ph

AU - Tamain, P.

PY - 2013

Y1 - 2013

N2 - The original and computationally efficient volume penalization technique Ref. [1], proposed for an isothermal plasma to recover the Bohm boundary condition at the plasma-obstacle interface, is extended to model 3D obstacles. It is then generalized to handle electron and ion temperatures in a 1D model. Results in 3D simulations show that the geometry of secondary limiter has an influence on the density and particle flux profiles, breaking its toroidal symmetry and introducing profile gaps of magnitude of 20%. On the other hand, the generalization of the penalization scheme to the non-isothermal case demands to deal with new Neumann conditions on the heat fluxes. Those boundary conditions require the introduction of new mask functions to ensure that the Bohm boundary condition remains satisfied.

AB - The original and computationally efficient volume penalization technique Ref. [1], proposed for an isothermal plasma to recover the Bohm boundary condition at the plasma-obstacle interface, is extended to model 3D obstacles. It is then generalized to handle electron and ion temperatures in a 1D model. Results in 3D simulations show that the geometry of secondary limiter has an influence on the density and particle flux profiles, breaking its toroidal symmetry and introducing profile gaps of magnitude of 20%. On the other hand, the generalization of the penalization scheme to the non-isothermal case demands to deal with new Neumann conditions on the heat fluxes. Those boundary conditions require the introduction of new mask functions to ensure that the Bohm boundary condition remains satisfied.

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VL - 438

SP - S625-S628

JO - Journal of Nuclear Materials

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Penalization technique to model wall-component impact on heat and mass transport in the tokamak edge

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