Three-dimensional distortions of the tokamak plasma boundary: boundary displacements in the presence of resonant magnetic perturbations
Artikel i vetenskaplig tidskrift, 2014

The three-dimensional plasma boundary displacements induced by applied non-axisymmetric magnetic perturbations have been measured in ASDEX Upgrade, DIII-D, JET, MAST and NSTX. The displacements arising from applied resonant magnetic perturbations (RMPs) are measured up to +/- 5% of the minor radius in present-day machines. Good agreement can be found between different experimental measurements and a range of models-be it vacuum field line tracing, ideal three-dimensional MHD equilibrium modelling, or nonlinear plasma amplification. The agreement of the various experimental measurements with the different predictions from these models is presented, and the regions of applicability of each discussed. The measured displacement of the outboard boundary from various machines is found to correlate approximately linearly with the applied resonant field predicted by vacuum modelling (though it should be emphasized that one should not infer that vacuum modelling accurately predicts the displacement inside the plasma). The RMP-induced displacements foreseen in ITER are expected to lie within the range of those predicted by the different models, meaning less than +/- 1.75% (+/- 3.5 cm) of the minor radius in the H-mode baseline and less than +/- 2.5% (+/- 5 cm) in a 9MA plasma. Whilst a displacement of 7 cm peak-to-peak in the baseline scenario is marginally acceptable from both a plasma control and heat loading perspective, it is important that ITER adopts a plasma control system which can account for a three-dimensional boundary corrugation to avoid an n = 0 correction which would otherwise locally exacerbate the displacement caused by the applied fields.

ITER

edge-localized modes

physics

pedestal

stability

Författare

I. T. Chapman

Culham Lab

M. Becoulet

Le Commissariat à l’Énergie Atomique et aux Énergies Alternatives (CEA)

T. Bird

Max Planck-institutet

J. Canik

Oak Ridge National Laboratory

M. Cianciosa

Auburn University

W. A. Cooper

Ecole Polytechnique Federale De Lausanne

T. Evans

General Atomics

N. Ferraro

General Atomics

C. Fuchs

Max Planck-institutet

M. Gryaznevich

Culham Lab

Y. Gribov

ITER

C. Ham

Culham Lab

J. Hanson

Auburn University

G. T. A. Huijsmans

ITER

A. Kirk

Culham Lab

S. Lazerson

Princeton Plasma Physics Laboratory

Y. Liang

Forschungszentrum Jülich

I. Lupelli

Culham Lab

R. A. Moyer

University of California

C. Nuehrenberg

Max Planck-institutet

F. Orain

Le Commissariat à l’Énergie Atomique et aux Énergies Alternatives (CEA)

D. Orlov

University of California

W. Suttrop

Max Planck-institutet

Dimitriy Yadykin

Chalmers, Rymd- och geovetenskap, Plasmafysik och fusionsenergi

Nuclear Fusion

0029-5515 (ISSN)

Vol. 54 Article no. 083006-

Ämneskategorier

Fusion, plasma och rymdfysik

DOI

10.1088/0029-5515/54/8/083006