TY - JOUR
T1 - The H-mode pedestal, ELMs and TF ripple effects in JT-60U/JET dimensionless identity experiments
AU - Saibene, G.
AU - Oyama, N.
AU - Lönnroth, J.
AU - Andrew, Y.
AU - de la Luna, E.
AU - Giroud, C.
AU - Huysmans, G.T.A.
AU - Kamada, Y.
AU - Kempenaars, M.A.H.
AU - Loarte, A.
AU - McDonald, D.
AU - Nave, M.M.F.
AU - Meiggs, A.
AU - Parail, V.
AU - Sartori, R.
AU - Sharapov, S.
AU - Stober, J.
AU - Suzuki, T.
AU - Takechi, M.
AU - Toi, K.
AU - Urano, H.
PY - 2007/8/1
Y1 - 2007/8/1
N2 - This paper summarizes results of dimensionless identity experiments in
JT-60U and JET, aimed at the comparison of the H-mode pedestal and ELM
behaviour in the two devices. Given their similar size, dimensionless
matched plasmas are also similar in their dimensional parameters (in
particular, the plasma minor radius a is the same in JET and JT-60U).
Power and density scans were carried out at two values of Ip,
providing a q scan (q95 = 3.1 and 5.1) with fixed (and
matched) toroidal field. Contrary to initial expectations, a
dimensionless match between the two devices was quite difficult to
achieve. In general, pped in JT-60U is lower than in JET and,
at low q, the pedestal pressure of JT-60U with a Type I ELMy edge is
matched in JET only in the Type III ELM regime. At q95 = 5.1,
a dimensionless match in ρ*, ν* and
βp,ped is obtained with Type I ELMs, but only with low
power JET H-modes. These results motivated a closer investigation of
experimental conditions in the two devices, to identify possible
'hidden' physics that prevents obtaining a good match of pedestal values
over a large range of plasmas parameters. Ripple-induced ion losses of
the medium bore plasma used in JT-60U for the similarity experiments are
identified as the main difference with JET. The magnitude of the JT-60U
ripple losses is sufficient to induce counter-toroidal rotation in
co-injected plasma. The influence of ripple losses was demonstrated at
q95 = 5.1: reducing ripple losses by ap2 (from 4.3 to 1.9 MW)
by replacing positive with negative neutral beam injection at
approximately constant Pin resulted in an increased
pped in JT-60U, providing a good match to full power JET
H-modes. At the same time, the counter-toroidal rotation decreased.
Physics mechanisms relating ripple losses to pedestal performance are
not yet identified, and the possible role of velocity shear in the
pedestal stability, as well as the possible influence of ripple on
thermal ion transport are briefly discussed. Toroidal rotation of the
ITER reference inductive Q = 10 H-mode is predicted to be rather low, of
the order of ~1/10 of the frequency of typical JET H-modes. Nonetheless,
fast ion ripple losses in that scenario are also predicted to be
negligible (
AB - This paper summarizes results of dimensionless identity experiments in
JT-60U and JET, aimed at the comparison of the H-mode pedestal and ELM
behaviour in the two devices. Given their similar size, dimensionless
matched plasmas are also similar in their dimensional parameters (in
particular, the plasma minor radius a is the same in JET and JT-60U).
Power and density scans were carried out at two values of Ip,
providing a q scan (q95 = 3.1 and 5.1) with fixed (and
matched) toroidal field. Contrary to initial expectations, a
dimensionless match between the two devices was quite difficult to
achieve. In general, pped in JT-60U is lower than in JET and,
at low q, the pedestal pressure of JT-60U with a Type I ELMy edge is
matched in JET only in the Type III ELM regime. At q95 = 5.1,
a dimensionless match in ρ*, ν* and
βp,ped is obtained with Type I ELMs, but only with low
power JET H-modes. These results motivated a closer investigation of
experimental conditions in the two devices, to identify possible
'hidden' physics that prevents obtaining a good match of pedestal values
over a large range of plasmas parameters. Ripple-induced ion losses of
the medium bore plasma used in JT-60U for the similarity experiments are
identified as the main difference with JET. The magnitude of the JT-60U
ripple losses is sufficient to induce counter-toroidal rotation in
co-injected plasma. The influence of ripple losses was demonstrated at
q95 = 5.1: reducing ripple losses by ap2 (from 4.3 to 1.9 MW)
by replacing positive with negative neutral beam injection at
approximately constant Pin resulted in an increased
pped in JT-60U, providing a good match to full power JET
H-modes. At the same time, the counter-toroidal rotation decreased.
Physics mechanisms relating ripple losses to pedestal performance are
not yet identified, and the possible role of velocity shear in the
pedestal stability, as well as the possible influence of ripple on
thermal ion transport are briefly discussed. Toroidal rotation of the
ITER reference inductive Q = 10 H-mode is predicted to be rather low, of
the order of ~1/10 of the frequency of typical JET H-modes. Nonetheless,
fast ion ripple losses in that scenario are also predicted to be
negligible (
U2 - 10.1088/0029-5515/47/8/031
DO - 10.1088/0029-5515/47/8/031
M3 - Article
SN - 0029-5515
VL - 47
SP - 969
EP - 983
JO - Nuclear Fusion
JF - Nuclear Fusion
IS - 8
ER -