2D divertor design calculations for the national high-power advanced torus experiment

J. M. Canik; R. Maingi; L. Owen; J. Menard; R. Goldston; M. Kotschenreuther; P. Valanju; S. Mahajan

doi:10.1016/j.jnucmat.2009.01.143

2D divertor design calculations for the national high-power advanced torus experiment

J. M. Canik
, R. Maingi
, L. Owen
, J. Menard
, R. Goldston
, M. Kotschenreuther
, P. Valanju
, S. Mahajan

Fusion Energy Division

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

6 Scopus citations

Abstract

The national high-power advanced torus experiment is a concept for a new facility to address the FESAC theme of 'taming the plasma-material interface'. This concept exploits the compactness and excellent access provided by low aspect ratio to achieve a high ratio of exhaust power to major radius in order to study the integration of high-performance, long-pulse plasmas with a reactor-relevant high heat flux plasma boundary. Predictions of the scrape-off-layer plasma characteristics are presented, as calculated with the 2D edge modeling code SOLPS. Calculations in a variety of magnetic geometries indicate that very high levels of divertor heat flux can be expected, with peak values far in excess of the power handling capabilities of presently-used materials. Possible methods to reduce the heat flux to acceptable levels are discussed.

Original language	English
Pages (from-to)	315-318
Number of pages	4
Journal	Journal of Nuclear Materials
Volume	390-391
Issue number	1
DOIs	https://doi.org/10.1016/j.jnucmat.2009.01.143
State	Published - Jun 15 2009

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10.1016/j.jnucmat.2009.01.143

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title = "2D divertor design calculations for the national high-power advanced torus experiment",

abstract = "The national high-power advanced torus experiment is a concept for a new facility to address the FESAC theme of 'taming the plasma-material interface'. This concept exploits the compactness and excellent access provided by low aspect ratio to achieve a high ratio of exhaust power to major radius in order to study the integration of high-performance, long-pulse plasmas with a reactor-relevant high heat flux plasma boundary. Predictions of the scrape-off-layer plasma characteristics are presented, as calculated with the 2D edge modeling code SOLPS. Calculations in a variety of magnetic geometries indicate that very high levels of divertor heat flux can be expected, with peak values far in excess of the power handling capabilities of presently-used materials. Possible methods to reduce the heat flux to acceptable levels are discussed.",

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T1 - 2D divertor design calculations for the national high-power advanced torus experiment

AU - Canik, J. M.

AU - Maingi, R.

AU - Owen, L.

AU - Menard, J.

AU - Goldston, R.

AU - Kotschenreuther, M.

AU - Valanju, P.

AU - Mahajan, S.

PY - 2009/6/15

Y1 - 2009/6/15

N2 - The national high-power advanced torus experiment is a concept for a new facility to address the FESAC theme of 'taming the plasma-material interface'. This concept exploits the compactness and excellent access provided by low aspect ratio to achieve a high ratio of exhaust power to major radius in order to study the integration of high-performance, long-pulse plasmas with a reactor-relevant high heat flux plasma boundary. Predictions of the scrape-off-layer plasma characteristics are presented, as calculated with the 2D edge modeling code SOLPS. Calculations in a variety of magnetic geometries indicate that very high levels of divertor heat flux can be expected, with peak values far in excess of the power handling capabilities of presently-used materials. Possible methods to reduce the heat flux to acceptable levels are discussed.

AB - The national high-power advanced torus experiment is a concept for a new facility to address the FESAC theme of 'taming the plasma-material interface'. This concept exploits the compactness and excellent access provided by low aspect ratio to achieve a high ratio of exhaust power to major radius in order to study the integration of high-performance, long-pulse plasmas with a reactor-relevant high heat flux plasma boundary. Predictions of the scrape-off-layer plasma characteristics are presented, as calculated with the 2D edge modeling code SOLPS. Calculations in a variety of magnetic geometries indicate that very high levels of divertor heat flux can be expected, with peak values far in excess of the power handling capabilities of presently-used materials. Possible methods to reduce the heat flux to acceptable levels are discussed.

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ER -

2D divertor design calculations for the national high-power advanced torus experiment

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