Physics aspects of the compact ignition tokamak

D. Post; W. Houlberg; G. Bateman; L. Bromberg; D. Cohn; P. Colestock; M. Hughes; D. Ignat; R. Izzo; S. Jardin; C. Kieras-Phillips; L. P. Ku; G. Kuo-Petravic; B. Lipschultz; R. Parker; C. Paulson; Y. K.M. Peng; M. Petravic; M. Phillips; N. Pomphrey; J. Schmidt; D. Strickler; A. Todd; N. Uckan; R. White; S. Wolfe; K. Young

doi:10.1088/0031-8949/1987/T16/011

Physics aspects of the compact ignition tokamak

D. Post, W. Houlberg, G. Bateman, L. Bromberg, D. Cohn, P. Colestock, M. Hughes, D. Ignat, R. Izzo, S. Jardin, C. Kieras-Phillips, L. P. Ku, G. Kuo-Petravic, B. Lipschultz, R. Parker, C. Paulson, Y. K.M. Peng, M. Petravic, M. Phillips, N. PomphreyJ. Schmidt, D. Strickler, A. Todd, N. Uckan, R. White, S. Wolfe, K. Young

PPPL Theory

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Abstract

The Compact Ignition Tokamak (CIT) is a proposed modest-size ignition experiment designed to study the physics of alpha particle heating. The basic concept is to achieve ignition in a modest-size minimum cost experiment by using a high plasma density to achieve required for ignition. The high density requires a high toroidal field (10 T). The high toroidal field allows a large plasma current (10 MA) which provides a high level of ohmic heating, improves the energy confinement, and allows a relatively high beta (6%). The present CIT design also has a high degree of elongation (1.8) to aid in producing the large plasma current. A double null poloidal divertor and pellet injection are part of the design to provide impurity and particle control, improve the confinement, and provide flexibility for improving the plasma profiles. Auxiliary heating is expected to be necessary to achieve ignition, and 10-20 MW of ICRF is to be provided.

Original language	English (US)
Pages (from-to)	89-106
Number of pages	18
Journal	Physica Scripta
Volume	1987
Issue number	T16
DOIs	https://doi.org/10.1088/0031-8949/1987/T16/011
State	Published - Jan 1 1987

All Science Journal Classification (ASJC) codes

Atomic and Molecular Physics, and Optics
Mathematical Physics
Condensed Matter Physics

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10.1088/0031-8949/1987/T16/011

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Post, D., Houlberg, W., Bateman, G., Bromberg, L., Cohn, D., Colestock, P., Hughes, M., Ignat, D., Izzo, R., Jardin, S., Kieras-Phillips, C., Ku, L. P., Kuo-Petravic, G., Lipschultz, B., Parker, R., Paulson, C., Peng, Y. K. M., Petravic, M., Phillips, M., ... Young, K. (1987). Physics aspects of the compact ignition tokamak. Physica Scripta, 1987(T16), 89-106. https://doi.org/10.1088/0031-8949/1987/T16/011

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title = "Physics aspects of the compact ignition tokamak",

abstract = "The Compact Ignition Tokamak (CIT) is a proposed modest-size ignition experiment designed to study the physics of alpha particle heating. The basic concept is to achieve ignition in a modest-size minimum cost experiment by using a high plasma density to achieve required for ignition. The high density requires a high toroidal field (10 T). The high toroidal field allows a large plasma current (10 MA) which provides a high level of ohmic heating, improves the energy confinement, and allows a relatively high beta (6\%). The present CIT design also has a high degree of elongation (1.8) to aid in producing the large plasma current. A double null poloidal divertor and pellet injection are part of the design to provide impurity and particle control, improve the confinement, and provide flexibility for improving the plasma profiles. Auxiliary heating is expected to be necessary to achieve ignition, and 10-20 MW of ICRF is to be provided.",

author = "D. Post and W. Houlberg and G. Bateman and L. Bromberg and D. Cohn and P. Colestock and M. Hughes and D. Ignat and R. Izzo and S. Jardin and C. Kieras-Phillips and Ku, \{L. P.\} and G. Kuo-Petravic and B. Lipschultz and R. Parker and C. Paulson and Peng, \{Y. K.M.\} and M. Petravic and M. Phillips and N. Pomphrey and J. Schmidt and D. Strickler and A. Todd and N. Uckan and R. White and S. Wolfe and K. Young",

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month = jan,

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doi = "10.1088/0031-8949/1987/T16/011",

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Post, D, Houlberg, W, Bateman, G, Bromberg, L, Cohn, D, Colestock, P, Hughes, M, Ignat, D, Izzo, R, Jardin, S, Kieras-Phillips, C, Ku, LP, Kuo-Petravic, G, Lipschultz, B, Parker, R, Paulson, C, Peng, YKM, Petravic, M, Phillips, M, Pomphrey, N, Schmidt, J, Strickler, D, Todd, A, Uckan, N, White, R, Wolfe, S & Young, K 1987, 'Physics aspects of the compact ignition tokamak', Physica Scripta, vol. 1987, no. T16, pp. 89-106. https://doi.org/10.1088/0031-8949/1987/T16/011

TY - JOUR

T1 - Physics aspects of the compact ignition tokamak

AU - Post, D.

AU - Houlberg, W.

AU - Bateman, G.

AU - Bromberg, L.

AU - Cohn, D.

AU - Colestock, P.

AU - Hughes, M.

AU - Ignat, D.

AU - Izzo, R.

AU - Jardin, S.

AU - Kieras-Phillips, C.

AU - Ku, L. P.

AU - Kuo-Petravic, G.

AU - Lipschultz, B.

AU - Parker, R.

AU - Paulson, C.

AU - Peng, Y. K.M.

AU - Petravic, M.

AU - Phillips, M.

AU - Pomphrey, N.

AU - Schmidt, J.

AU - Strickler, D.

AU - Todd, A.

AU - Uckan, N.

AU - White, R.

AU - Wolfe, S.

AU - Young, K.

PY - 1987/1/1

Y1 - 1987/1/1

N2 - The Compact Ignition Tokamak (CIT) is a proposed modest-size ignition experiment designed to study the physics of alpha particle heating. The basic concept is to achieve ignition in a modest-size minimum cost experiment by using a high plasma density to achieve required for ignition. The high density requires a high toroidal field (10 T). The high toroidal field allows a large plasma current (10 MA) which provides a high level of ohmic heating, improves the energy confinement, and allows a relatively high beta (6%). The present CIT design also has a high degree of elongation (1.8) to aid in producing the large plasma current. A double null poloidal divertor and pellet injection are part of the design to provide impurity and particle control, improve the confinement, and provide flexibility for improving the plasma profiles. Auxiliary heating is expected to be necessary to achieve ignition, and 10-20 MW of ICRF is to be provided.

AB - The Compact Ignition Tokamak (CIT) is a proposed modest-size ignition experiment designed to study the physics of alpha particle heating. The basic concept is to achieve ignition in a modest-size minimum cost experiment by using a high plasma density to achieve required for ignition. The high density requires a high toroidal field (10 T). The high toroidal field allows a large plasma current (10 MA) which provides a high level of ohmic heating, improves the energy confinement, and allows a relatively high beta (6%). The present CIT design also has a high degree of elongation (1.8) to aid in producing the large plasma current. A double null poloidal divertor and pellet injection are part of the design to provide impurity and particle control, improve the confinement, and provide flexibility for improving the plasma profiles. Auxiliary heating is expected to be necessary to achieve ignition, and 10-20 MW of ICRF is to be provided.

UR - https://www.scopus.com/pages/publications/84956127467

UR - https://www.scopus.com/inward/citedby.url?scp=84956127467&partnerID=8YFLogxK

U2 - 10.1088/0031-8949/1987/T16/011

DO - 10.1088/0031-8949/1987/T16/011

M3 - Article

AN - SCOPUS:84956127467

SN - 0031-8949

VL - 1987

SP - 89

EP - 106

JO - Physica Scripta

JF - Physica Scripta

IS - T16

ER -

Physics aspects of the compact ignition tokamak

Abstract

All Science Journal Classification (ASJC) codes

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