Samenvatting
An assessment is presented of the impact of recent magnetohydrodynamic
research results on performance projections for reactor scale tokamaks
as exemplified by the ITER Final Design Report (ITER/FDR) facility. For
nominal ELMy H mode operation, the presence and amplitude of
neoclassical tearing modes governs the achievable β value. Recent
work finds that the scaling of β at which such modes onset agrees
well with a polarization drift model, with the consequence that, with
reasonable assumptions regarding seed island width, the mode onset
β will be lower in reactor scale tokamaks than in contemporary
devices. Confinement degradation by such modes, on the other hand,
depends on relative saturated island size which is governed principally
by β and secondarily by ν* effects on bootstrap current density.
Relative saturated island size should be comparable in present and
reactor devices. DT ITER demonstration discharges in JET exhibited no
confinement degradation at the planned ITER operating value of
βN = 2.2. Theory indicates that electron cyclotron
current drive can either stabilize these modes or appreciably reduce
saturated island size. Turning to operation in candidate steady state,
reverse shear, high bootstrap fraction configurations, wall
stabilization of external kink modes is effective while the plasma is
rotating but (so far) rotation has not been maintained. Recent error
field observations in JET imply an error field size scaling that leads
to a projection that the ITER/FDR facility will be somewhat more
tolerant to error fields than thought previously. ICRF experiments on
JET and Alcator C-Mod indicate that plasmas heated by central energetic
particles have benign ELMs compared with the usual type 1 ELM of NBI
heated discharges.
Originele taal-2 | Engels |
---|---|
Pagina's (van-tot) | 2051-2054 |
Tijdschrift | Nuclear Fusion |
Volume | 39 |
Nummer van het tijdschrift | 11Y |
DOI's | |
Status | Gepubliceerd - 1 nov. 1999 |
Extern gepubliceerd | Ja |