Disruptions in JET

J. A. Wesson; R. D. Gill; M. Hugon; F. C. Schöller; J. A. Snipes; D. J. Ward; D. V. Bartlett; D. J. Campbell; P. A. Duperrex; A. W. Edwards; R. S. Granetz; C. Lowry; N. A.O. Gottardi; T. C. Hender; E. Lazzaro; P. J. Lomas; N. Lopes Cardozo; K. F. Mast; M. F.F. Nave; N. A. Salmon; P. Smeulders; P. R. Thomas; B. J.D. Tubbing; M. F. Turner; A. Weller

doi:10.1088/0029-5515/29/4/009

Disruptions in JET

J. A. Wesson, R. D. Gill, M. Hugon, F. C. Schöller, J. A. Snipes, D. J. Ward, D. V. Bartlett, D. J. Campbell, P. A. Duperrex, A. W. Edwards, R. S. Granetz, C. Lowry, N. A.O. Gottardi, T. C. Hender, E. Lazzaro, P. J. Lomas, N. Lopes Cardozo, K. F. Mast, M. F.F. Nave, N. A. SalmonP. Smeulders, P. R. Thomas, B. J.D. Tubbing, M. F. Turner, A. Weller

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Abstract

In JET, both high density and low-q operation are limited by disruptions. The density limit disruptions are caused initially by impurity radiation. This causes a contraction of the plasma temperature profile and leads to an MHD unstable configuration. There is evidence of magnetic island formation resulting in minor disruptions. After several minor disruptions, a major disruption with a rapid energy quench occurs. This event takes place in two stages. In the first stage there is a loss of energy from the central region. In the second stage there is a more rapid drop to a very low temperature, apparently due to a dramatic increase in impurity radiation. The final current decay takes place in the resulting cold plasma. During the growth of the MHD instability the initially rotating mode is brought to rest. This mode locking is believed to be due to an electromagnetic interaction with the vacuum vessel and external magnetic field asymmetries. The low-q disruptions are remarkable for the precision with which they occur at q_Ψ = 2. These disruptions do not have extended precursors or minor disruptions. The instability grows and locks rapidly. The energy quench and current decay are generally similar to those of the density limit.

Original language	English (US)
Pages (from-to)	641-666
Number of pages	26
Journal	Nuclear Fusion
Volume	29
Issue number	4
DOIs	https://doi.org/10.1088/0029-5515/29/4/009
State	Published - Apr 1989
Externally published	Yes

All Science Journal Classification (ASJC) codes

Nuclear and High Energy Physics
Condensed Matter Physics

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10.1088/0029-5515/29/4/009

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Wesson, J. A., Gill, R. D., Hugon, M., Schöller, F. C., Snipes, J. A., Ward, D. J., Bartlett, D. V., Campbell, D. J., Duperrex, P. A., Edwards, A. W., Granetz, R. S., Lowry, C., Gottardi, N. A. O., Hender, T. C., Lazzaro, E., Lomas, P. J., Lopes Cardozo, N., Mast, K. F., Nave, M. F. F., ... Weller, A. (1989). Disruptions in JET. Nuclear Fusion, 29(4), 641-666. https://doi.org/10.1088/0029-5515/29/4/009

@article{1bccbcb9501f4210a51b432e586a12cc,

title = "Disruptions in JET",

abstract = "In JET, both high density and low-q operation are limited by disruptions. The density limit disruptions are caused initially by impurity radiation. This causes a contraction of the plasma temperature profile and leads to an MHD unstable configuration. There is evidence of magnetic island formation resulting in minor disruptions. After several minor disruptions, a major disruption with a rapid energy quench occurs. This event takes place in two stages. In the first stage there is a loss of energy from the central region. In the second stage there is a more rapid drop to a very low temperature, apparently due to a dramatic increase in impurity radiation. The final current decay takes place in the resulting cold plasma. During the growth of the MHD instability the initially rotating mode is brought to rest. This mode locking is believed to be due to an electromagnetic interaction with the vacuum vessel and external magnetic field asymmetries. The low-q disruptions are remarkable for the precision with which they occur at qΨ = 2. These disruptions do not have extended precursors or minor disruptions. The instability grows and locks rapidly. The energy quench and current decay are generally similar to those of the density limit.",

author = "Wesson, \{J. A.\} and Gill, \{R. D.\} and M. Hugon and Sch{\"o}ller, \{F. C.\} and Snipes, \{J. A.\} and Ward, \{D. J.\} and Bartlett, \{D. V.\} and Campbell, \{D. J.\} and Duperrex, \{P. A.\} and Edwards, \{A. W.\} and Granetz, \{R. S.\} and C. Lowry and Gottardi, \{N. A.O.\} and Hender, \{T. C.\} and E. Lazzaro and Lomas, \{P. J.\} and \{Lopes Cardozo\}, N. and Mast, \{K. F.\} and Nave, \{M. F.F.\} and Salmon, \{N. A.\} and P. Smeulders and Thomas, \{P. R.\} and Tubbing, \{B. J.D.\} and Turner, \{M. F.\} and A. Weller",

year = "1989",

month = apr,

doi = "10.1088/0029-5515/29/4/009",

language = "English (US)",

volume = "29",

pages = "641--666",

journal = "Nuclear Fusion",

issn = "0029-5515",

publisher = "IOP Publishing Ltd.",

number = "4",

}

Wesson, JA, Gill, RD, Hugon, M, Schöller, FC, Snipes, JA, Ward, DJ, Bartlett, DV, Campbell, DJ, Duperrex, PA, Edwards, AW, Granetz, RS, Lowry, C, Gottardi, NAO, Hender, TC, Lazzaro, E, Lomas, PJ, Lopes Cardozo, N, Mast, KF, Nave, MFF, Salmon, NA, Smeulders, P, Thomas, PR, Tubbing, BJD, Turner, MF & Weller, A 1989, 'Disruptions in JET', Nuclear Fusion, vol. 29, no. 4, pp. 641-666. https://doi.org/10.1088/0029-5515/29/4/009

TY - JOUR

T1 - Disruptions in JET

AU - Wesson, J. A.

AU - Gill, R. D.

AU - Hugon, M.

AU - Schöller, F. C.

AU - Snipes, J. A.

AU - Ward, D. J.

AU - Bartlett, D. V.

AU - Campbell, D. J.

AU - Duperrex, P. A.

AU - Edwards, A. W.

AU - Granetz, R. S.

AU - Lowry, C.

AU - Gottardi, N. A.O.

AU - Hender, T. C.

AU - Lazzaro, E.

AU - Lomas, P. J.

AU - Lopes Cardozo, N.

AU - Mast, K. F.

AU - Nave, M. F.F.

AU - Salmon, N. A.

AU - Smeulders, P.

AU - Thomas, P. R.

AU - Tubbing, B. J.D.

AU - Turner, M. F.

AU - Weller, A.

PY - 1989/4

Y1 - 1989/4

N2 - In JET, both high density and low-q operation are limited by disruptions. The density limit disruptions are caused initially by impurity radiation. This causes a contraction of the plasma temperature profile and leads to an MHD unstable configuration. There is evidence of magnetic island formation resulting in minor disruptions. After several minor disruptions, a major disruption with a rapid energy quench occurs. This event takes place in two stages. In the first stage there is a loss of energy from the central region. In the second stage there is a more rapid drop to a very low temperature, apparently due to a dramatic increase in impurity radiation. The final current decay takes place in the resulting cold plasma. During the growth of the MHD instability the initially rotating mode is brought to rest. This mode locking is believed to be due to an electromagnetic interaction with the vacuum vessel and external magnetic field asymmetries. The low-q disruptions are remarkable for the precision with which they occur at qΨ = 2. These disruptions do not have extended precursors or minor disruptions. The instability grows and locks rapidly. The energy quench and current decay are generally similar to those of the density limit.

AB - In JET, both high density and low-q operation are limited by disruptions. The density limit disruptions are caused initially by impurity radiation. This causes a contraction of the plasma temperature profile and leads to an MHD unstable configuration. There is evidence of magnetic island formation resulting in minor disruptions. After several minor disruptions, a major disruption with a rapid energy quench occurs. This event takes place in two stages. In the first stage there is a loss of energy from the central region. In the second stage there is a more rapid drop to a very low temperature, apparently due to a dramatic increase in impurity radiation. The final current decay takes place in the resulting cold plasma. During the growth of the MHD instability the initially rotating mode is brought to rest. This mode locking is believed to be due to an electromagnetic interaction with the vacuum vessel and external magnetic field asymmetries. The low-q disruptions are remarkable for the precision with which they occur at qΨ = 2. These disruptions do not have extended precursors or minor disruptions. The instability grows and locks rapidly. The energy quench and current decay are generally similar to those of the density limit.

UR - https://www.scopus.com/pages/publications/0024646959

UR - https://www.scopus.com/inward/citedby.url?scp=0024646959&partnerID=8YFLogxK

U2 - 10.1088/0029-5515/29/4/009

DO - 10.1088/0029-5515/29/4/009

M3 - Article

AN - SCOPUS:0024646959

SN - 0029-5515

VL - 29

SP - 641

EP - 666

JO - Nuclear Fusion

JF - Nuclear Fusion

IS - 4

ER -

Disruptions in JET

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