Development of Coupled IMPGYRO-SOLPS Codes for Analyzing Tokamak Plasmas with Tungsten Impurities

M. Toma; X. Bonnin; K. Hoshino; A. Hatayama; R. Schneider; D. Coster

doi:10.1002/ctpp.201210032

Development of Coupled IMPGYRO-SOLPS Codes for Analyzing Tokamak Plasmas with Tungsten Impurities

M. Toma, X. Bonnin, K. Hoshino, A. Hatayama, R. Schneider, D. Coster

Research output: Contribution to journal › Article › peer-review

5 Citations (Scopus)

Abstract

For the purpose of a consistent treatment of tungsten impurity together with background plasma, coupling of the IMPGYRO and SOLPS codes has been undertaken. The fluid part of SOLPS transfers the background plasma data to the IMPGYRO kinetic impurity code, while IMPGYRO transfers the effect of tungsten impurities to SOLPS as particle, momentum and energy source/sink terms. An initial test calculation has been performed under a simple model for impurity generation. The impurity content in the system reaches a quasi-steady state in the coupled calculation. The temporal history of the simulation shows that an initial impurity generation results in a relatively large radiation loss and plasma cooling. The cooler plasma suppresses further impurity generation, leading to a quasi-steady state in the coupled calculation.

Original language	English
Pages (from-to)	450-454
Number of pages	5
Journal	Contributions to Plasma Physics
Volume	52
Issue number	5-6
DOIs	https://doi.org/10.1002/ctpp.201210032
Publication status	Published - 2012 Jun
Externally published	Yes

Keywords

IMPGYRO
Impurity
SOL/divertor
SOLPS
Tungsten

ASJC Scopus subject areas

Condensed Matter Physics

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10.1002/ctpp.201210032

Cite this

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abstract = "For the purpose of a consistent treatment of tungsten impurity together with background plasma, coupling of the IMPGYRO and SOLPS codes has been undertaken. The fluid part of SOLPS transfers the background plasma data to the IMPGYRO kinetic impurity code, while IMPGYRO transfers the effect of tungsten impurities to SOLPS as particle, momentum and energy source/sink terms. An initial test calculation has been performed under a simple model for impurity generation. The impurity content in the system reaches a quasi-steady state in the coupled calculation. The temporal history of the simulation shows that an initial impurity generation results in a relatively large radiation loss and plasma cooling. The cooler plasma suppresses further impurity generation, leading to a quasi-steady state in the coupled calculation.",

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AU - Toma, M.

AU - Bonnin, X.

AU - Hoshino, K.

AU - Hatayama, A.

AU - Schneider, R.

AU - Coster, D.

PY - 2012/6

Y1 - 2012/6

N2 - For the purpose of a consistent treatment of tungsten impurity together with background plasma, coupling of the IMPGYRO and SOLPS codes has been undertaken. The fluid part of SOLPS transfers the background plasma data to the IMPGYRO kinetic impurity code, while IMPGYRO transfers the effect of tungsten impurities to SOLPS as particle, momentum and energy source/sink terms. An initial test calculation has been performed under a simple model for impurity generation. The impurity content in the system reaches a quasi-steady state in the coupled calculation. The temporal history of the simulation shows that an initial impurity generation results in a relatively large radiation loss and plasma cooling. The cooler plasma suppresses further impurity generation, leading to a quasi-steady state in the coupled calculation.

AB - For the purpose of a consistent treatment of tungsten impurity together with background plasma, coupling of the IMPGYRO and SOLPS codes has been undertaken. The fluid part of SOLPS transfers the background plasma data to the IMPGYRO kinetic impurity code, while IMPGYRO transfers the effect of tungsten impurities to SOLPS as particle, momentum and energy source/sink terms. An initial test calculation has been performed under a simple model for impurity generation. The impurity content in the system reaches a quasi-steady state in the coupled calculation. The temporal history of the simulation shows that an initial impurity generation results in a relatively large radiation loss and plasma cooling. The cooler plasma suppresses further impurity generation, leading to a quasi-steady state in the coupled calculation.

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KW - Impurity

KW - SOL/divertor

KW - SOLPS

KW - Tungsten

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Development of Coupled IMPGYRO-SOLPS Codes for Analyzing Tokamak Plasmas with Tungsten Impurities

Abstract

Keywords

ASJC Scopus subject areas

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