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Beta-limiting instabilities and global mode stabilization in the National Spherical Torus Experiment

Authors :
E. J. Synakowski
A.M. Garofalo
W. Zhu
Dan Stutman
D.A. Gates
J.M. Bialek
J.E. Menard
S.M. Kaye
M. Peng
M. Ono
E.D. Fredrickson
D. Mueller
G.A. Navratil
B.P. LeBlanc
M. G. Bell
R.E. Bell
L.L. Lao
S.A. Sabbagh
R. Maingi
F. Paoletti
Alan H. Glasser
Source :
Physics of Plasmas. 9:2085-2092
Publication Year :
2002
Publisher :
AIP Publishing, 2002.

Abstract

Research on the stability of spherical torus plasmas at and above the no-wall beta limit is being addressed on the National Spherical Torus Experiment [M. Ono et al., Nucl. Fusion 40, 557 (2000)], that has produced low aspect ratio plasmas, R/a∼1.27 at plasma current exceeding 1.4 MA with high energy confinement (TauE/TauE_ITER89P>2). Toroidal and normalized beta have exceeded 25% and 4.3, respectively, in q∼7 plasmas. The beta limit is observed to increase and then saturate with increasing li. The stability factor βN/li has reached 6, limited by sudden beta collapses. Increased pressure peaking leads to a decrease in βN. Ideal stability analysis of equilibria reconstructed with EFIT [L. L. Lao et al., Nucl. Fusion 25, 1611 (1985)] shows that the plasmas are at the no-wall beta limit for the n=1 kink/ballooning mode. Low aspect ratio and high edge q theoretically alter the plasma stability and mode structure compared to standard tokamak configurations. Below the no-wall limit, stability calculations show the perturbed radial field is maximized near the center column and mode stability is not highly effected by a nearby conducting wall due to the short poloidal wavelength in this region. In contrast, as beta reaches and exceeds the no-wall limit, the mode becomes strongly ballooning with long poloidal wavelength at large major radius and is highly wall stabilized. In this way, wall stabilization is more effective at higher beta in low aspect ratio geometry. The resistive wall mode has been observed in plasmas exceeding the ideal no-wall beta limit and leads to rapid toroidal rotation damping across the plasma core.

Details

ISSN :
10897674 and 1070664X
Volume :
9
Database :
OpenAIRE
Journal :
Physics of Plasmas
Accession number :
edsair.doi...........cbef0dc546bc06ff96b68d7c45112ab8
Full Text :
https://doi.org/10.1063/1.1468230