TY - JOUR
T1 - Edge transport barrier in JET hot ion H modes
AU - Guo, H.Y.
AU - Lomas, P.J.
AU - Parail, V.V.
AU - Andrew, P.
AU - Balet, B.
AU - Conway, G.D.
AU - DeEsch, B.
AU - Gowers, C.W.
AU - von Hellermann, M.G.
AU - Huysmans, G.T.A.
AU - Jones, T.T.C.
AU - Keilhacker, M.
AU - König, R.W.T.
AU - Maas, A.
AU - Marcus, F.B.
AU - Matthews, G.F.
AU - Nave, M. F.F.
AU - Rimini, F.G.
AU - Smith, R.J.
AU - Stamp, M.F.
AU - Taroni, A.
AU - Thomas, P.R.
AU - Zastrow, K.-D.
PY - 2000/1/1
Y1 - 2000/1/1
N2 - The effects of changing beam and plasma species on the edge transport
barrier are investigated for ELM-free hot ion H mode discharges from the
recent DT experiments on JET. The measured pressure at the top of the
pedestal is higher for mixed deuterium and tritium and pure tritium
plasmas over and above the level measured in pure deuterium plasmas at
the same heating power. The pedestal pressure increases with beam
tritium concentration for mixed deuterium-tritium beam injection into
deuterium plasmas where the measured edge tritium concentration remains
low. Alpha heating plays a significant role in the core of such plasmas,
and the possible impact on the edge is discussed together with possible
direct isotopic effects. Heuristic models for the transport barrier
width are proposed, and used to explore a wider range of edge
measurements including full power DD and DT pulses. This analysis
supports the plasma current and mass dependence for a barrier width set
by the orbit loss of either thermal or fast ions, though it does not
unambiguously distinguish between them. The fast ion hypothesis could
well account for some of the JET observations, though more theoretical
work and direct experimental measurement would be required to confirm
this. An ad hoc model for the power loss through the separatrix,
Ploss propto nedge2
Zeff,edgeIp-1, is proposed based on
neoclassical theory, a ballooning limit to the edge gradient and a
barrier width set by the poloidal ion gyroradius. Such a model is
compared with experimental data from JET. In particular, the model
ascribes the systematic difference in loss power between the Mark I and
Mark II divertors to the change in the measured Zeff. This
change in Zeff is consistent with the observed change in
impurity production, which is described in some detail, together with a
possible explanation provided by the temperature dependence of chemical
sputtering.
AB - The effects of changing beam and plasma species on the edge transport
barrier are investigated for ELM-free hot ion H mode discharges from the
recent DT experiments on JET. The measured pressure at the top of the
pedestal is higher for mixed deuterium and tritium and pure tritium
plasmas over and above the level measured in pure deuterium plasmas at
the same heating power. The pedestal pressure increases with beam
tritium concentration for mixed deuterium-tritium beam injection into
deuterium plasmas where the measured edge tritium concentration remains
low. Alpha heating plays a significant role in the core of such plasmas,
and the possible impact on the edge is discussed together with possible
direct isotopic effects. Heuristic models for the transport barrier
width are proposed, and used to explore a wider range of edge
measurements including full power DD and DT pulses. This analysis
supports the plasma current and mass dependence for a barrier width set
by the orbit loss of either thermal or fast ions, though it does not
unambiguously distinguish between them. The fast ion hypothesis could
well account for some of the JET observations, though more theoretical
work and direct experimental measurement would be required to confirm
this. An ad hoc model for the power loss through the separatrix,
Ploss propto nedge2
Zeff,edgeIp-1, is proposed based on
neoclassical theory, a ballooning limit to the edge gradient and a
barrier width set by the poloidal ion gyroradius. Such a model is
compared with experimental data from JET. In particular, the model
ascribes the systematic difference in loss power between the Mark I and
Mark II divertors to the change in the measured Zeff. This
change in Zeff is consistent with the observed change in
impurity production, which is described in some detail, together with a
possible explanation provided by the temperature dependence of chemical
sputtering.
U2 - 10.1088/0029-5515/40/1/306
DO - 10.1088/0029-5515/40/1/306
M3 - Article
SN - 0029-5515
VL - 40
SP - 69
EP - 89
JO - Nuclear Fusion
JF - Nuclear Fusion
IS - 1
ER -