Steady state operation of spherical tokamaks

R. J. Akers; A. Bond; R. J. Buttery; P. G. Carolan; G. F. Counsell; G. Cunningham; S. J. Fielding; C. G. Gimblett; M. Gryaznevich; R. J. Hastie; P. Helander; T. C. Hender; P. J. Knight; C. N. Lashmore-Davies; G. P. Maddison; T. J. Martin; K. G. McClements; A. W. Morris; M. R. O'Brien; C. Ribeiro; C. M. Roach; D. C. Robinson; A. Sykes; G. M. Voss; M. J. Walsh; H. R. Wilson; F. S. Zaitsev

doi:10.1088/0029-5515/40/6/317

Steady state operation of spherical tokamaks

R. J. Akers
, A. Bond
, R. J. Buttery
, P. G. Carolan
, G. F. Counsell
, G. Cunningham
, S. J. Fielding
, C. G. Gimblett
, M. Gryaznevich
, R. J. Hastie
, P. Helander
, T. C. Hender
, P. J. Knight
, C. N. Lashmore-Davies
, G. P. Maddison
, T. J. Martin
, K. G. McClements
, A. W. Morris
, M. R. O'Brien
, C. Ribeiro

C. M. Roach, D. C. Robinson, A. Sykes, G. M. Voss, M. J. Walsh, H. R. Wilson, F. S. Zaitsev

Fusion Energy Division

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

38 Scopus citations

Abstract

For a fusion power plant to be economically and technologically attractive, it should be as compact as possible and capable of 'steady state' operation. One approach is based upon the spherical tokamak (ST) concept. This configuration features many of the qualities of the conventional aspect ratio tokamak, such as good confinement and MHD stability, together with a number of highly promising features for the realization of a cost effective, steady state fusion power core. In particular, it allows high β capability due to the high I/B achievable at low A and strong, natural shaping of the configuration, together with the possibility of approaching 100% pressure driven currents through high natural elongation and access to second stability to ideal ballooning modes. The physics insights gained from experiments on START are discussed and the theoretical modelling work summarized, describing how the beneficial properties of STs can be combined in steady state ST power plant designs such as the Culham STPP concept. Where appropriate, we shall refer to the two new mega-amp machines MAST and NSTX, both designed for a plasma duration approaching the plasma current relaxation time and also other new, smaller, STs, designed to expand the knowledge gained so far.

Original language	English
Pages (from-to)	1223-1244
Number of pages	22
Journal	Nuclear Fusion
Volume	40
Issue number	6
DOIs	https://doi.org/10.1088/0029-5515/40/6/317
State	Published - Jun 2000

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Akers, R. J., Bond, A., Buttery, R. J., Carolan, P. G., Counsell, G. F., Cunningham, G., Fielding, S. J., Gimblett, C. G., Gryaznevich, M., Hastie, R. J., Helander, P., Hender, T. C., Knight, P. J., Lashmore-Davies, C. N., Maddison, G. P., Martin, T. J., McClements, K. G., Morris, A. W., O'Brien, M. R., ... Zaitsev, F. S. (2000). Steady state operation of spherical tokamaks. Nuclear Fusion, 40(6), 1223-1244. https://doi.org/10.1088/0029-5515/40/6/317

@article{484075da994a472f9397c878bd3b0215,

title = "Steady state operation of spherical tokamaks",

abstract = "For a fusion power plant to be economically and technologically attractive, it should be as compact as possible and capable of 'steady state' operation. One approach is based upon the spherical tokamak (ST) concept. This configuration features many of the qualities of the conventional aspect ratio tokamak, such as good confinement and MHD stability, together with a number of highly promising features for the realization of a cost effective, steady state fusion power core. In particular, it allows high β capability due to the high I/B achievable at low A and strong, natural shaping of the configuration, together with the possibility of approaching 100\% pressure driven currents through high natural elongation and access to second stability to ideal ballooning modes. The physics insights gained from experiments on START are discussed and the theoretical modelling work summarized, describing how the beneficial properties of STs can be combined in steady state ST power plant designs such as the Culham STPP concept. Where appropriate, we shall refer to the two new mega-amp machines MAST and NSTX, both designed for a plasma duration approaching the plasma current relaxation time and also other new, smaller, STs, designed to expand the knowledge gained so far.",

author = "Akers, \{R. J.\} and A. Bond and Buttery, \{R. J.\} and Carolan, \{P. G.\} and Counsell, \{G. F.\} and G. Cunningham and Fielding, \{S. J.\} and Gimblett, \{C. G.\} and M. Gryaznevich and Hastie, \{R. J.\} and P. Helander and Hender, \{T. C.\} and Knight, \{P. J.\} and Lashmore-Davies, \{C. N.\} and Maddison, \{G. P.\} and Martin, \{T. J.\} and McClements, \{K. G.\} and Morris, \{A. W.\} and O'Brien, \{M. R.\} and C. Ribeiro and Roach, \{C. M.\} and Robinson, \{D. C.\} and A. Sykes and Voss, \{G. M.\} and Walsh, \{M. J.\} and Wilson, \{H. R.\} and Zaitsev, \{F. S.\}",

year = "2000",

month = jun,

doi = "10.1088/0029-5515/40/6/317",

language = "English",

volume = "40",

pages = "1223--1244",

journal = "Nuclear Fusion",

issn = "0029-5515",

publisher = "IOP Publishing",

number = "6",

}

Akers, RJ, Bond, A, Buttery, RJ, Carolan, PG, Counsell, GF, Cunningham, G, Fielding, SJ, Gimblett, CG, Gryaznevich, M, Hastie, RJ, Helander, P, Hender, TC, Knight, PJ, Lashmore-Davies, CN, Maddison, GP, Martin, TJ, McClements, KG, Morris, AW, O'Brien, MR, Ribeiro, C, Roach, CM, Robinson, DC, Sykes, A, Voss, GM, Walsh, MJ, Wilson, HR & Zaitsev, FS 2000, 'Steady state operation of spherical tokamaks', Nuclear Fusion, vol. 40, no. 6, pp. 1223-1244. https://doi.org/10.1088/0029-5515/40/6/317

TY - JOUR

T1 - Steady state operation of spherical tokamaks

AU - Akers, R. J.

AU - Bond, A.

AU - Buttery, R. J.

AU - Carolan, P. G.

AU - Counsell, G. F.

AU - Cunningham, G.

AU - Fielding, S. J.

AU - Gimblett, C. G.

AU - Gryaznevich, M.

AU - Hastie, R. J.

AU - Helander, P.

AU - Hender, T. C.

AU - Knight, P. J.

AU - Lashmore-Davies, C. N.

AU - Maddison, G. P.

AU - Martin, T. J.

AU - McClements, K. G.

AU - Morris, A. W.

AU - O'Brien, M. R.

AU - Ribeiro, C.

AU - Roach, C. M.

AU - Robinson, D. C.

AU - Sykes, A.

AU - Voss, G. M.

AU - Walsh, M. J.

AU - Wilson, H. R.

AU - Zaitsev, F. S.

PY - 2000/6

Y1 - 2000/6

N2 - For a fusion power plant to be economically and technologically attractive, it should be as compact as possible and capable of 'steady state' operation. One approach is based upon the spherical tokamak (ST) concept. This configuration features many of the qualities of the conventional aspect ratio tokamak, such as good confinement and MHD stability, together with a number of highly promising features for the realization of a cost effective, steady state fusion power core. In particular, it allows high β capability due to the high I/B achievable at low A and strong, natural shaping of the configuration, together with the possibility of approaching 100% pressure driven currents through high natural elongation and access to second stability to ideal ballooning modes. The physics insights gained from experiments on START are discussed and the theoretical modelling work summarized, describing how the beneficial properties of STs can be combined in steady state ST power plant designs such as the Culham STPP concept. Where appropriate, we shall refer to the two new mega-amp machines MAST and NSTX, both designed for a plasma duration approaching the plasma current relaxation time and also other new, smaller, STs, designed to expand the knowledge gained so far.

AB - For a fusion power plant to be economically and technologically attractive, it should be as compact as possible and capable of 'steady state' operation. One approach is based upon the spherical tokamak (ST) concept. This configuration features many of the qualities of the conventional aspect ratio tokamak, such as good confinement and MHD stability, together with a number of highly promising features for the realization of a cost effective, steady state fusion power core. In particular, it allows high β capability due to the high I/B achievable at low A and strong, natural shaping of the configuration, together with the possibility of approaching 100% pressure driven currents through high natural elongation and access to second stability to ideal ballooning modes. The physics insights gained from experiments on START are discussed and the theoretical modelling work summarized, describing how the beneficial properties of STs can be combined in steady state ST power plant designs such as the Culham STPP concept. Where appropriate, we shall refer to the two new mega-amp machines MAST and NSTX, both designed for a plasma duration approaching the plasma current relaxation time and also other new, smaller, STs, designed to expand the knowledge gained so far.

UR - https://www.scopus.com/pages/publications/0033705541

U2 - 10.1088/0029-5515/40/6/317

DO - 10.1088/0029-5515/40/6/317

M3 - Article

AN - SCOPUS:0033705541

SN - 0029-5515

VL - 40

SP - 1223

EP - 1244

JO - Nuclear Fusion

JF - Nuclear Fusion

IS - 6

ER -

Steady state operation of spherical tokamaks

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