TY - JOUR
T1 - Non-resonant magnetic braking on JET and TEXTOR
JF - Nuclear Fusion
Y1 - 2012
A1 - Sun, Y.
A1 - Liang, Y.
A1 - K.C. Shaing
A1 - Liu, Y. Q.
A1 - Koslowski, H. R.
A1 - Jachmich, S.
A1 - Alper, B.
A1 - Alfier, A.
A1 - Asunta, O.
A1 - Buratti, P.
A1 - Corrigan, G.
A1 - Delabie, E.
A1 - Giroud, C.
A1 - Gryaznevich, M. P.
A1 - Harting, D.
A1 - Hender, T.
A1 - Nardon, E.
A1 - Naulin, V.
A1 - Parail, V.
A1 - Tala, T.
A1 - C. Wiegmann
A1 - Wiesen, S.
A1 - T. Zhang
A1 - JET-EFDA Contributors
AB - The non-resonant magnetic braking effect induced by a non-axisymmetric magnetic perturbation is investigated on JET and TEXTOR. The collisionality dependence of the torque induced by the n = 1, where n is the toroidal mode number, magnetic perturbation generated by the error field correction coils on JET is observed. The observed torque is located mainly in the plasma core (normalized radius ρ < 0.4) and increases with decreasing collisionality. The neoclassical toroidal plasma viscosity (NTV) torque in the collisionless regime is modelled using the numerical solution of the bounce-averaged drift kinetic equation. The calculated collisionality dependence of the NTV torque is in good agreement with the experimental observation on JET. The reason for this collisionality dependence is that the torque in the plasma core on JET mainly comes from the flux of the trapped electrons, which are still mainly in the 1/ ν regime. The strongest NTV torque on JET is also located near the plasma core. The magnitude of the NTV torque strongly depends on the plasma response, which is also discussed in this paper. There is no obvious braking effect with n = 2 magnetic perturbation generated by the dynamic ergodic divertor on TEXTOR, which is consistent with the NTV modelling.
VL - 52
UR - http://stacks.iop.org/0029-5515/52/i=8/a=083007
U1 - FP
U2 - PDG
U5 - 900f56a8eca3bece5bb8db32c792b0b9
ER -