On plasma rotation with toroidal magnetic field ripple and no external momentum input

C. Fenzi; X. Garbet; E. Trier; P. Hennequin; C. Bourdelle; T. Aniel; G. Colledani; P. Devynck; C. Gil; L. Manenc; M. Schneider; J. L. Segui

doi:10.1088/0029-5515/51/10/103038

On plasma rotation with toroidal magnetic field ripple and no external momentum input

C. Fenzi
, X. Garbet
, E. Trier
, P. Hennequin
, C. Bourdelle
, T. Aniel
, G. Colledani
, P. Devynck
, C. Gil
, Gürcan
, L. Manenc
, M. Schneider
, J. L. Segui

CEA Cadarache

Research output: Contribution to journal › Article › peer-review

Abstract

Ripple-induced thermal loss effect on plasma rotation is investigated in a set of Ohmic L-mode plasmas performed in Tore Supra, and comparisons with neoclassical predictions including ripple are performed. Adjusting the size of the plasma, the ripple amplitude has been varied from 0.5% to 5.5% at the plasma boundary, keeping the edge safety factor constant. The toroidal flow dynamics is understood as being likely dominated by turbulence transport driven processes at low ripple amplitude, while the ripple-induced toroidal friction becomes dominant at high ripple. In the latter case, the velocity tends remarkably towards the neoclassical prediction (counter-current rotation). The radial electric field is not affected by the ripple variation and remains well described by its neoclassical prediction. Finally, the poloidal velocity is of the order of the neoclassical prediction at high ripple amplitude, but significantly departs from it at low ripple.

Original language	English
Article number	103038
Journal	Nuclear Fusion
Volume	51
Issue number	10
DOIs	https://doi.org/10.1088/0029-5515/51/10/103038
Publication status	Published - 1 Oct 2011

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Cite this

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title = "On plasma rotation with toroidal magnetic field ripple and no external momentum input",

abstract = "Ripple-induced thermal loss effect on plasma rotation is investigated in a set of Ohmic L-mode plasmas performed in Tore Supra, and comparisons with neoclassical predictions including ripple are performed. Adjusting the size of the plasma, the ripple amplitude has been varied from 0.5\% to 5.5\% at the plasma boundary, keeping the edge safety factor constant. The toroidal flow dynamics is understood as being likely dominated by turbulence transport driven processes at low ripple amplitude, while the ripple-induced toroidal friction becomes dominant at high ripple. In the latter case, the velocity tends remarkably towards the neoclassical prediction (counter-current rotation). The radial electric field is not affected by the ripple variation and remains well described by its neoclassical prediction. Finally, the poloidal velocity is of the order of the neoclassical prediction at high ripple amplitude, but significantly departs from it at low ripple.",

author = "C. Fenzi and X. Garbet and E. Trier and P. Hennequin and C. Bourdelle and T. Aniel and G. Colledani and P. Devynck and C. Gil and G{\"u}rcan and L. Manenc and M. Schneider and Segui, \{J. L.\}",

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doi = "10.1088/0029-5515/51/10/103038",

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TY - JOUR

T1 - On plasma rotation with toroidal magnetic field ripple and no external momentum input

AU - Fenzi, C.

AU - Garbet, X.

AU - Trier, E.

AU - Hennequin, P.

AU - Bourdelle, C.

AU - Aniel, T.

AU - Colledani, G.

AU - Devynck, P.

AU - Gil, C.

AU - Gürcan,

AU - Manenc, L.

AU - Schneider, M.

AU - Segui, J. L.

PY - 2011/10/1

Y1 - 2011/10/1

N2 - Ripple-induced thermal loss effect on plasma rotation is investigated in a set of Ohmic L-mode plasmas performed in Tore Supra, and comparisons with neoclassical predictions including ripple are performed. Adjusting the size of the plasma, the ripple amplitude has been varied from 0.5% to 5.5% at the plasma boundary, keeping the edge safety factor constant. The toroidal flow dynamics is understood as being likely dominated by turbulence transport driven processes at low ripple amplitude, while the ripple-induced toroidal friction becomes dominant at high ripple. In the latter case, the velocity tends remarkably towards the neoclassical prediction (counter-current rotation). The radial electric field is not affected by the ripple variation and remains well described by its neoclassical prediction. Finally, the poloidal velocity is of the order of the neoclassical prediction at high ripple amplitude, but significantly departs from it at low ripple.

AB - Ripple-induced thermal loss effect on plasma rotation is investigated in a set of Ohmic L-mode plasmas performed in Tore Supra, and comparisons with neoclassical predictions including ripple are performed. Adjusting the size of the plasma, the ripple amplitude has been varied from 0.5% to 5.5% at the plasma boundary, keeping the edge safety factor constant. The toroidal flow dynamics is understood as being likely dominated by turbulence transport driven processes at low ripple amplitude, while the ripple-induced toroidal friction becomes dominant at high ripple. In the latter case, the velocity tends remarkably towards the neoclassical prediction (counter-current rotation). The radial electric field is not affected by the ripple variation and remains well described by its neoclassical prediction. Finally, the poloidal velocity is of the order of the neoclassical prediction at high ripple amplitude, but significantly departs from it at low ripple.

U2 - 10.1088/0029-5515/51/10/103038

DO - 10.1088/0029-5515/51/10/103038

M3 - Article

AN - SCOPUS:80052597430

SN - 0029-5515

VL - 51

JO - Nuclear Fusion

JF - Nuclear Fusion

IS - 10

M1 - 103038

ER -

On plasma rotation with toroidal magnetic field ripple and no external momentum input

Abstract

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