Magnetic configuration studies in a Compact Torsatron

An overview is presented of an experimental program of magnetic field line mapping on the research-grade Compact Auburn Torsatron (CAT). The vacuum magnetic flux surfaces of the CAT device have been experimentally mapped in a variety of magnetic configurations. The results are compared with an exten...

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Bibliographic Details
Published in:Journal of fusion energy 1993-09, Vol.12 (3), p.261-271
Main Authors: Knowlton, Stephen F., Gandy, Rex F., Hanson, James D., Hartwell, Gregory J., Lin, Hong
Format: Article
Language:English
Subjects:
70 PLASMA PHYSICS AND FUSION TECHNOLOGY
700430 - Fusion Technology- Magnet Coils & Fields- (1992-)
CLOSED PLASMA DEVICES
MAGNETIC FIELD CONFIGURATIONS
MAGNETIC ISLANDS
MAGNETIC SURFACES
STELLARATORS
THERMONUCLEAR DEVICES
TORSATRON STELLARATORS
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Summary:An overview is presented of an experimental program of magnetic field line mapping on the research-grade Compact Auburn Torsatron (CAT). The vacuum magnetic flux surfaces of the CAT device have been experimentally mapped in a variety of magnetic configurations. The results are compared with an extensive computer model in order to validate the coil design. In initial field mapping experiments, an up-down symmetry was identified in the vacuum magnetic surfaces, and was corrected with the use of a radial trim field. Magnetic islands are observed and their size has been reduced, also through the use of auxiliary trim coils. The Compact Auburn Torsatron is equipped with two pairs of large Helmholtz coils producing mutually orthogonal magnetic fields in the horizontal plane, and two pairs of helical saddle coils wound directly on the toroidal vacuum vessel. These trim coils are used to control the size and phase of the t = 1/2 magnetic island. Through a systematic variation of trim field components, the authors demonstrate a reduction of the inherent t = 1/2 magnetic island size by a factor of three. The technique is applicable to correcting small error fields in larger helical confinement devices. The measurements of island size are compared with measurements of magnetic field line rotation within the island, and are found to be in good agreement with first-order perturbation theory.
ISSN:0164-0313
1572-9591
DOI:10.1007/BF01079669