DIFFER
DIFFER Publication

Parametric dependences of momentum pinch and Prandtl number in JET

Author
Abstract

Several parametric scans have been performed to study momentum transport on JET. A neutral beam injection modulation technique has been applied to separate the diffusive and convective momentum transport terms. The magnitude of the inward momentum pinch depends strongly on the inverse density gradient length, with an experimental scaling for the pinch number being - Rv(pinch)/chi(phi) = 1.2R/L(n) + 1.4. There is no dependence of the pinch number on collisionality, whereas the pinch seems to depend weakly on q-profile, the pinch number decreasing with increasing q. The Prandtl number was not found to depend either on R/L(n), collisionality or on q. The gyro-kinetic simulations show qualitatively similar dependence of the pinch number on R/L(n), but the dependence is weaker in the simulations. Gyro-kinetic simulations do not find any clear parametric dependence in the Prandtl number, in agreement with experiments, but the experimental values are larger than the simulated ones, in particular in L-mode plasmas. The extrapolation of these results to ITER illustrates that at large enough R/L(n) > 2 the pinch number becomes large enough (>3-4) to make the rotation profile peaked, provided that the edge rotation is non-zero. And this rotation peaking can be achieved with small or even with no core torque source. The absolute value of the core rotation is still very challenging to predict partly due to the lack of the present knowledge of the rotation at the plasma edge, partly due to insufficient understanding of 3D effects like braking and partly due to the uncertainties in the extrapolation of the present momentum transport results to a larger device.

Year of Publication
2011
Journal
Nuclear Fusion
Volume
51
Number
12
Issue
12
Number of Pages
123002
Date Published
Dec
Type of Article
Article
ISBN Number
0029-5515
DOI
10.1088/0029-5515/51/12/123002
PId
76d59f479b968143a6d6d759b5aaecd1
Alternate Journal
Nucl. Fusion
Journal Article
Download citation