EFDA-JET-PR(13)48
Modelling of JET Hybrid Scenarios with GLF23 Transport Model: ExB Shear Stabilization of Anomalous Transport
The ExB shear stabilisation of anomalous transport in JET hybrid discharges is studied via selfconsistent predictive modelling of electron and ion temperature, ion density and toroidal rotation velocity performed with the GLF23 model. The ExB shear stabilisation factor (parameter aE in the GLF23 model) is adjusted to predict accurately the four simulated quantities under different experimental conditions, and the uncertainty in αE determined by 15% deviation between simulated and measured quantities is estimated. A correlation of αE with toroidal rotation velocity and ExB shearing rate is found in the low density plasmas, suggesting that the turbulence quench rule may be more complicated than assumed in the GLF23 model with constant αE. For the selected discharges the best predictive accuracy is obtained by using weak/no ExB shear stabilisation (i.e. αE 0) at low toroidal angular frequency (Ω < 60krad/s), even in the scenarios with the current overshoot, and αE = 0.9 at high frequency (Ω > 100krad/s). Interestingly, a weak ExB shear stabilisation of anomalous transport is found in the medium density strongly rotating discharge. An importance of linear βe stabilisation in this discharge is estimated and compared to the low density discharge with equally high βe. The toroidal rotation velocity is well predicted here by assuming that the momentum diffusion coefficient is a fraction of thermal ion diffusivity. Taking into account the aE and Prandtl number with their uncertainties determined in the modelling of JET hybrid discharges, the performance of ITER hybrid scenario with optimised heat mix (33MW of NBI and 20MW of ECCD) is estimated showing the importance of toroidal rotation for achieving Q > 5.