Maximizing the ion temperature in an electron heated plasma: from WEST towards larger devices
P. Manas, J.F. Artaud, C. Bourdelle, V. Ostuni, J. Moralès, J. Citrin, the WEST Team
Abstract
Abstract In electron heated plasmas, as the power increases, it is experimentally reported that the ion temperature ( T i ) saturates while the electron temperature ( T e ) increases [Beurskens NF 2022]. As on AUG, W7X and elsewhere, T i saturates around 1.5 keV in WEST L-mode electron heated plasmas while T e reaches 4 keV. Simulations within the integrated model METIS have been compared against a whole WEST campaign consisting mostly of L-mode plasmas with Lower Hybrid heating ranging from 1 to 5.5 MW. In METIS, the collisional equipartition is modeled as well as the turbulent heat transport using the neural network regression of the quasilinear gyrokinetic code QuaLiKiz. The observed T i saturation is well captured by the modeling framework. The saturation correlates with a low ratio of the energy confinement time to the volume averaged electron-ion collisional heat exchange time. It is then shown that T i saturation in electron heated plasma is due to an equipartition time higher than the energy confinement time. In larger devices, no T i saturation is expected nor predicted by physics based integrated modeling used in this work, thanks to equipartition times sufficiently shorter than the energy confinement time.