Open AccessProgress towards Steady State at Low Aspect Ratio on the National Spherical Torus Experiment (NSTX)
Author(s) -
D.A. Gates, J. Menard, R. Maingi, S. Kaye, S.A. Sabbagh, S. Diem, J.R.Wilson, M.G. Bell, R.E. Bell, J. Ferron, E.D. Fredrickson, C.E. Kessel, B.P. LeBlanc, F. Levinton, J. Manickam, D. Mueller, R. Raman, T. Stevenson, D. Stutman, G. Taylor, K. Tritz, H. Yu, and the NSTX Research Team
Publication year - 2007
Language(s) - English
Resource type - Reports
DOI - 10.2172/961738
Subject(s) - divertor , plasma , safety factor , atomic physics , current (fluid) , physics , steady state (chemistry) , pulse (music) , diffusion , torus , magnetohydrodynamics , fusion power , spherical tokamak , aspect ratio (aeronautics) , computational physics , tokamak , chemistry , nuclear physics , voltage , thermodynamics , geometry , optoelectronics , quantum mechanics , mathematics
Modifications to the plasma control capabilities and poloidal field coils of the National Spherical Torus Experiment (NSTX) have enabled a significant enhancement in shaping capability which has led to the transient achievement of a record shape factor (S ≡ q95 (Iρ⁄ αΒτ)) of ∼41 (MA m−1 Τ−1) simultaneous with a record plasma elongation of κ ≡ β ⁄ α ∼ 3. This result was obtained using isoflux control and real-time equilibrium reconstruction. Achieving high shape factor together with tolerable divertor loading is an important result for future ST burning plasma experiments as exemplified by studies for future ST reactor concepts, as well as neutron producing devices, which rely on achieving high shape factors in order to achieve steady state operation while maintaining MHD stability. Statistical evidence is presented which demonstrates the expected correlation between increased shaping and improved plasma performance