Results from the MAST spherical tokamak

Authors :: D Taylor
C. Byrom
R. J. Akers
M. B. Hood
I. Lehane
S.J. Fielding
K. Stammers
G. Cunningham
E. R. Arends
G.J. McArdle
H. R. Wilson
C. Ribeiro
A. W. Morris
Mikhail Gryaznevich
A. Kirk
S.J. Manhood
M. R. Tournianski
G. F. Counsell
M. J. Walsh
P. G. Carolan
R.J. Buttery
A. Sykes
J. Dowling
R.J. Hayward
S. Warder
Romualdo Martín
M. Valovic
D.C. Robinson
N. J. Conway
D. Ciric
A. R. Field
M. Price
J.-W. Ahn
Vladimir Shevchenko
G. P. Maddison
G.M. Voss
Per Helander
T. Pinfold
K.B. Axon
S. Gee
M. R. Dunstan
M. Mgrath
A. Tabasso
M. Cox
H. F. Meyer
A. Darke
M. P. S. Nightingale
B. Lloyd
Source :: Proceedings of the 19th IEEE/IPSS Symposium on Fusion Engineering. 19th SOFE (Cat. No.02CH37231).
Publication Year :: 2003
Publisher :: IEEE, 2003.
Abstract: The MAST (Mega-Amp Spherical Tokamak) experiment has been operational since Jan 2000. Results from MAST are important both in evaluating the potential of future ST fusion devices, and in developing understanding of processes relevant to conventional aspect ratio tokamaks. In this paper methods of initiating, ramping up, and sustaining the high plasma currents associated with ST fusion devices are discussed. New physics results, including the effectiveness of inboard gas puffing, the threshold power required for the L-H transition, and the 'natural' divertor configuration are given. Plans for improvements during 2002 are outlined.

Subjects :: Physics
Nuclear physics
Mast (sailing)
Tokamak
High plasma
law
Divertor
Nuclear engineering
Plasma diagnostics
Spherical tokamak
Plasma density
law.invention

Database :: OpenAIRE
Journal :: Proceedings of the 19th IEEE/IPSS Symposium on Fusion Engineering. 19th SOFE (Cat. No.02CH37231)
Accession number :: edsair.doi...........69d3187f4e6a011deeb9651006f7e359
Full Text :: https://doi.org/10.1109/fusion.2002.1027734