Free boundary equilibrium in 3D tokamaks with toroidal rotation

W. A. Cooper, D. Brunetti, J. M. Faustin, J. P. Graves, D. Pfefferlé, M. Raghunathan, O. Sauter, T. M. Tran, I. T. Chapman, C. J. Ham, N. Aiba, The MAST team, JET contributors

Research output: Contribution to journalArticle

2 Citations (Scopus)

Abstract

The three-dimensional VMEC equilibrium solver has been adapted to numerically investigate the approximate toroidal rotation model we have derived. We concentrate our applications on the simulation of JET snakes and MAST long-lived modes under free boundary conditions. Helical core solutions are triggered when 〈β〉 exceeds a threshold value, typically 2.7% in JET-like plasmas. A large plasma current and edge bootstrap current can drive helical core formations at arbitrarily small 〈β〉 in which the ideal saturated internal kink coexists with an ideal saturated external kink structure of opposite phase. The centrifugal force linked with the rotation has the effect of displacing the plasma column away from the major axis, but does not alter significantly the magnitude of the edge corrugation of the plasma. Error field correction coil currents in JET-like configurations increase the outer midplane distortions by 2 cm. The edge bootstrap current enhances the edge modulation of the plasma driven by the core snake deformations in MAST.

Original languageEnglish
Article number063032
JournalNuclear Fusion
Volume55
Issue number6
DOIs
Publication statusPublished - 1 Jun 2015
Externally publishedYes

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