TY - JOUR
T1 - High fusion performance from deuterium-tritium plasmas in JET
AU - JET Team
AU - Keilhacker, M.
AU - Gibson, A.
AU - Gormezano, C.
AU - Lomas, P.J.
AU - Thomas, P.R.
AU - Watkins, M.L.
AU - Andrew, P.
AU - Balet, B.
AU - Borba, D.
AU - Challis, C.D.
AU - Coffey, I.
AU - Cottrell, G.A.
AU - DeEsch, H.P.L.
AU - Deliyanakis, N.
AU - Fasoli, A.
AU - Gowers, C.W.
AU - Guo, H.Y.
AU - Huysmans, G.T.A.
AU - Jones, T.T.C.
AU - Kerner, W.
AU - König, R.W.T.
AU - Loughlin, M.J.
AU - Maas, A.
AU - Marcus, F.B.
AU - Nave, M.F.F.
AU - Rimini, F.G.
AU - Sadler, G.J.
AU - Sharapov, S.E.
AU - Sips, G.
AU - Smeulders, P.
AU - Söldner, F.X.
AU - Taroni, A.
AU - Tubbing, B.J.D.
AU - von Hellermann, M.G.
AU - Ward, D.J.
PY - 1999/2/1
Y1 - 1999/2/1
N2 - High fusion power experiments using DT mixtures in ELM-free H mode and
optimized shear regimes in JET are reported. A fusion power of 16.1 MW
has been produced in an ELM-free H mode at 4.2 MA/3.6 T. The transient
value of the fusion amplification factor was 0.95+/-0.17, consistent
with the high value of
nDT(0)τEdiaTi(0) = 8.7
× 1020+/-20% m-3 s keV, and was maintained
for about half an energy confinement time until excessive edge pressure
gradients resulted in discharge termination by MHD instabilities. The
ratio of DD to DT fusion powers (from separate but otherwise similar
discharges) showed the expected factor of 210, validating DD projections
of DT performance for similar pressure profiles and good plasma mixture
control, which was achieved by loading the vessel walls with the
appropriate DT mix. Magnetic fluctuation spectra showed no evidence of
Alfvénic instabilities driven by alpha particles, in agreement
with theoretical model calculations. Alpha particle heating has been
unambiguously observed, its effect being separated successfully from
possible isotope effects on energy confinement by varying the tritium
concentration in otherwise similar discharges. The scan showed that
there was no, or at most a very weak, isotope effect on the energy
confinement time. The highest electron temperature was clearly
correlated with the maximum alpha particle heating power and the optimum
DT mixture; the maximum increase was 1.3+/-0.23 keV with 1.3 MW of alpha
particle heating power, consistent with classical expectations for alpha
particle confinement and heating. In the optimized shear regime, clear
internal transport barriers were established for the first time in DT,
with a power similar to that required in DD. The ion thermal
conductivity in the plasma core approached neoclassical levels. Real
time power control maintained the plasma core close to limits set by
pressure gradient driven MHD instabilities, allowing 8.2 MW of DT fusion
power with
nDT(0)τEdiaTi(0) approx
1021 m-3 s keV, even though full optimization was
not possible within the imposed neutron budget. In addition,
quasi-steady-state discharges with simultaneous internal and edge
transport barriers have been produced with high confinement and a fusion
power of up to 7 MW these double barrier discharges show a great
potential for steady state operation. © 1999, Euratom
AB - High fusion power experiments using DT mixtures in ELM-free H mode and
optimized shear regimes in JET are reported. A fusion power of 16.1 MW
has been produced in an ELM-free H mode at 4.2 MA/3.6 T. The transient
value of the fusion amplification factor was 0.95+/-0.17, consistent
with the high value of
nDT(0)τEdiaTi(0) = 8.7
× 1020+/-20% m-3 s keV, and was maintained
for about half an energy confinement time until excessive edge pressure
gradients resulted in discharge termination by MHD instabilities. The
ratio of DD to DT fusion powers (from separate but otherwise similar
discharges) showed the expected factor of 210, validating DD projections
of DT performance for similar pressure profiles and good plasma mixture
control, which was achieved by loading the vessel walls with the
appropriate DT mix. Magnetic fluctuation spectra showed no evidence of
Alfvénic instabilities driven by alpha particles, in agreement
with theoretical model calculations. Alpha particle heating has been
unambiguously observed, its effect being separated successfully from
possible isotope effects on energy confinement by varying the tritium
concentration in otherwise similar discharges. The scan showed that
there was no, or at most a very weak, isotope effect on the energy
confinement time. The highest electron temperature was clearly
correlated with the maximum alpha particle heating power and the optimum
DT mixture; the maximum increase was 1.3+/-0.23 keV with 1.3 MW of alpha
particle heating power, consistent with classical expectations for alpha
particle confinement and heating. In the optimized shear regime, clear
internal transport barriers were established for the first time in DT,
with a power similar to that required in DD. The ion thermal
conductivity in the plasma core approached neoclassical levels. Real
time power control maintained the plasma core close to limits set by
pressure gradient driven MHD instabilities, allowing 8.2 MW of DT fusion
power with
nDT(0)τEdiaTi(0) approx
1021 m-3 s keV, even though full optimization was
not possible within the imposed neutron budget. In addition,
quasi-steady-state discharges with simultaneous internal and edge
transport barriers have been produced with high confinement and a fusion
power of up to 7 MW these double barrier discharges show a great
potential for steady state operation. © 1999, Euratom
U2 - 10.1088/0029-5515/39/2/306
DO - 10.1088/0029-5515/39/2/306
M3 - Article
SN - 0029-5515
VL - 39
SP - 209
EP - 234
JO - Nuclear Fusion
JF - Nuclear Fusion
IS - 2
ER -