Open AccessFivefold confinement time increase in the Madison Symmetric Torus using inductive poloidal current drive
Author(s) -
M. R. Stoneking,
N. E. Lanier,
S. C. Prager,
J. S. Sarff,
D. V. Sinitsyn
Publication year - 1996
Publication title -
osti oai (u.s. department of energy office of scientific and technical information)
Language(s) - English
Resource type - Reports
DOI - 10.2172/434481
Subject(s) - reversed field pinch , dynamo , pinch , current (fluid) , physics , amplitude , plasma , transient (computer programming) , beta (programming language) , magnetic field , steady state (chemistry) , ohmic contact , atomic physics , electric field , joule heating , mechanics , magnetohydrodynamics , optics , chemistry , nuclear physics , quantum mechanics , electrode , computer science , thermodynamics , programming language , operating system
Current profile control is employed in the Madison Symmetric Torus reversed field pinch to reduce the magnetic fluctuations responsible for anomalous transport. An inductive poloidal electric field pulse is applied in the sense to flatten the parallel current profile, reducing the dynamo fluctuation amplitude required to sustain the equilibrium. This technique demonstrates a substantial reduction in fluctuation amplitude (as much as 50%), and improvement in energy confinement (from 1 ms to 5 ms); a record low fluctuation (0.8%) and record high temperature (615 eV) for this device were observed simultaneously during current drive experiments. Plasma beta increases by 50% and the Ohmic input power is three times lower. Particle confinement improves and plasma impurity contamination is reduced. The results of the transient current drive experiments provide motivation for continuing development of steady-state current profile control strategies for the reversed field pinch
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