TY - JOUR
T1 - Stability analysis of improved confinement discharges
T2 - Internal transport barriers in Tore Supra and radiative improved mode in TEXTOR
AU - Bourdellea, C.
AU - Garbet, X.
AU - Hoang, G. T.
AU - Ongena, J.
AU - Budny, R. V.
PY - 2002/7
Y1 - 2002/7
N2 - Results of stability analysis are presented for two types of plasma with good confinement: internal transport barriers (ITBs) on Tore Supra and the radiative improved (RI) mode on TEXTOR. The stability analysis has been performed with an electrostatic linear gyrokinetic code, evaluating the growth rates of microinstabilities. The code developed, KINEZERO, is aimed at systematic microstability analysis. Therefore the trade-off between having perfect quantitative agreement and minimizing computation time is made in favour of the latter. In the plasmas analysed, it is found that the onset of the confinement improvement involves a trigger. For the ITB discharges, negative magnetic shear is involved, whereas for the RI discharges, the triggering role is played by the increase of the impurity concentration. Once the improved confinement is triggered, the simultaneous increases of temperature and density gradients imply an increase in both the growth rate and the rotation shearing rate. The rotation shear is found to be high enough to maintain an improved confinement through the stabilization of the large scale modes.
AB - Results of stability analysis are presented for two types of plasma with good confinement: internal transport barriers (ITBs) on Tore Supra and the radiative improved (RI) mode on TEXTOR. The stability analysis has been performed with an electrostatic linear gyrokinetic code, evaluating the growth rates of microinstabilities. The code developed, KINEZERO, is aimed at systematic microstability analysis. Therefore the trade-off between having perfect quantitative agreement and minimizing computation time is made in favour of the latter. In the plasmas analysed, it is found that the onset of the confinement improvement involves a trigger. For the ITB discharges, negative magnetic shear is involved, whereas for the RI discharges, the triggering role is played by the increase of the impurity concentration. Once the improved confinement is triggered, the simultaneous increases of temperature and density gradients imply an increase in both the growth rate and the rotation shearing rate. The rotation shear is found to be high enough to maintain an improved confinement through the stabilization of the large scale modes.
UR - http://www.scopus.com/inward/record.url?scp=0036648423&partnerID=8YFLogxK
U2 - 10.1088/0029-5515/42/7/312
DO - 10.1088/0029-5515/42/7/312
M3 - Article
AN - SCOPUS:0036648423
SN - 0029-5515
VL - 42
SP - 892
EP - 902
JO - Nuclear Fusion
JF - Nuclear Fusion
IS - 7
ER -