Toroidal rotation braking with low n external perturbation field on JET

Y. Sun; Y. Liang; H. R. Koslowski; S. Jachmich; A. Alfier; O. Asunta; G. Corrigan; C. Giroud; M. P. Gryaznevich; D. Harting; T. Hender; E. Nardon; V. Naulin; V. Parail; T. Tala; C. Wiegmann; S. Wiesen

Toroidal rotation braking with low n external perturbation field on JET

Y. Sun
, Y. Liang
, H. R. Koslowski
, S. Jachmich
, A. Alfier
, O. Asunta
, G. Corrigan
, C. Giroud
, M. P. Gryaznevich
, D. Harting
, T. Hender
, E. Nardon
, V. Naulin
, V. Parail
, T. Tala
, C. Wiegmann
, S. Wiesen

Laboratory for Plasma Physics

FORSCHUNGSZENTRUM JULICH GMBH
Consorzio Rfx
Helsinki University of Technology
Culham Centre for Fusion Energy
Technical University of Denmark

Publikation: Beitrag in Buch/Bericht/Konferenzband › Konferenzbeitrag › Begutachtung

Abstract

The experimentally measured torque profile of the perturbation field induced by the n=1 EFCC field, T_EFCC, is determined by momentum transport analysis using the JETTO code. The NBI torque is calculated by the PENCIL code. The perpendicular diffusion coefficient and pinch velocity profile are determined by fitting the evolution of the velocity after the switch-off of EFCC current. The T_EFCC has a global profile. The maximum torque is in the plasma central region, which is different from the observations on NSTX and DIII-D with higher n perturbation field. This torque is not localized at a certain rational surface and the velocity evolution is obviously different from that in the mode locking phase as also observed on NSTX. With the vacuum field approximation, the NTV torque in the collisionless regime is calculated and compared with the observed T_EFCC. The calculated NTV torque profile in the 1/ν regime agrees with the profile of T_EFCC, although its absolute value is a factor of 2 larger. The NTV torque in the ν regime from the boundary layer contribution is comparable to the measured torque. Therefore, the NTV torque is in the same order as the observed T_EFCC. The NTV torque is a good candidate to explain the non-resonant magnetic braking observed on JET with n=1 perturbation field.

Originalsprache	Englisch
Titel	36th EPS Conference on Plasma Physics 2009, EPS 2009 - Europhysics Conference Abstracts
Seiten	41-44
Seitenumfang	4
Publikationsstatus	Veröffentlicht - 2009
Veranstaltung	36th European Physical Society Conference on Plasma Physics 2009, EPS 2009 - Sofia, Bulgarien Dauer: 29 Juni 2009 → 3 Juli 2009

Publikationsreihe

Name	36th EPS Conference on Plasma Physics 2009, EPS 2009 - Europhysics Conference Abstracts
Band	33 E1

Konferenz

Konferenz	36th European Physical Society Conference on Plasma Physics 2009, EPS 2009
Land/Gebiet	Bulgarien
Ort	Sofia
Zeitraum	29/06/09 → 3/07/09

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Sun, Y., Liang, Y., Koslowski, H. R., Jachmich, S., Alfier, A., Asunta, O., Corrigan, G., Giroud, C., Gryaznevich, M. P., Harting, D., Hender, T., Nardon, E., Naulin, V., Parail, V., Tala, T., Wiegmann, C., & Wiesen, S. (2009). Toroidal rotation braking with low n external perturbation field on JET. in 36th EPS Conference on Plasma Physics 2009, EPS 2009 - Europhysics Conference Abstracts (S. 41-44). (36th EPS Conference on Plasma Physics 2009, EPS 2009 - Europhysics Conference Abstracts; Band 33 E1).

@inproceedings{f47b634227cb4e68b1df02f31579bd10,

title = "Toroidal rotation braking with low n external perturbation field on JET",

abstract = "The experimentally measured torque profile of the perturbation field induced by the n=1 EFCC field, TEFCC, is determined by momentum transport analysis using the JETTO code. The NBI torque is calculated by the PENCIL code. The perpendicular diffusion coefficient and pinch velocity profile are determined by fitting the evolution of the velocity after the switch-off of EFCC current. The TEFCC has a global profile. The maximum torque is in the plasma central region, which is different from the observations on NSTX and DIII-D with higher n perturbation field. This torque is not localized at a certain rational surface and the velocity evolution is obviously different from that in the mode locking phase as also observed on NSTX. With the vacuum field approximation, the NTV torque in the collisionless regime is calculated and compared with the observed TEFCC. The calculated NTV torque profile in the 1/ν regime agrees with the profile of TEFCC, although its absolute value is a factor of 2 larger. The NTV torque in the ν regime from the boundary layer contribution is comparable to the measured torque. Therefore, the NTV torque is in the same order as the observed TEFCC. The NTV torque is a good candidate to explain the non-resonant magnetic braking observed on JET with n=1 perturbation field.",

author = "Y. Sun and Y. Liang and Koslowski, \{H. R.\} and S. Jachmich and A. Alfier and O. Asunta and G. Corrigan and C. Giroud and Gryaznevich, \{M. P.\} and D. Harting and T. Hender and E. Nardon and V. Naulin and V. Parail and T. Tala and C. Wiegmann and S. Wiesen",

year = "2009",

language = "English",

isbn = "9781622763368",

series = "36th EPS Conference on Plasma Physics 2009, EPS 2009 - Europhysics Conference Abstracts",

pages = "41--44",

booktitle = "36th EPS Conference on Plasma Physics 2009, EPS 2009 - Europhysics Conference Abstracts",

note = "36th European Physical Society Conference on Plasma Physics 2009, EPS 2009 ; Conference date: 29-06-2009 Through 03-07-2009",

}

Sun, Y, Liang, Y, Koslowski, HR, Jachmich, S, Alfier, A, Asunta, O, Corrigan, G, Giroud, C, Gryaznevich, MP, Harting, D, Hender, T, Nardon, E, Naulin, V, Parail, V, Tala, T, Wiegmann, C & Wiesen, S 2009, Toroidal rotation braking with low n external perturbation field on JET. in 36th EPS Conference on Plasma Physics 2009, EPS 2009 - Europhysics Conference Abstracts. 36th EPS Conference on Plasma Physics 2009, EPS 2009 - Europhysics Conference Abstracts, Bd. 33 E1, S. 41-44, 36th European Physical Society Conference on Plasma Physics 2009, EPS 2009, Sofia, Bulgarien, 29/06/09.

Toroidal rotation braking with low n external perturbation field on JET. / Sun, Y.; Liang, Y.; Koslowski, H. R. et al.
36th EPS Conference on Plasma Physics 2009, EPS 2009 - Europhysics Conference Abstracts. 2009. S. 41-44 (36th EPS Conference on Plasma Physics 2009, EPS 2009 - Europhysics Conference Abstracts; Band 33 E1).

Publikation: Beitrag in Buch/Bericht/Konferenzband › Konferenzbeitrag › Begutachtung

TY - GEN

T1 - Toroidal rotation braking with low n external perturbation field on JET

AU - Sun, Y.

AU - Liang, Y.

AU - Koslowski, H. R.

AU - Jachmich, S.

AU - Alfier, A.

AU - Asunta, O.

AU - Corrigan, G.

AU - Giroud, C.

AU - Gryaznevich, M. P.

AU - Harting, D.

AU - Hender, T.

AU - Nardon, E.

AU - Naulin, V.

AU - Parail, V.

AU - Tala, T.

AU - Wiegmann, C.

AU - Wiesen, S.

PY - 2009

Y1 - 2009

N2 - The experimentally measured torque profile of the perturbation field induced by the n=1 EFCC field, TEFCC, is determined by momentum transport analysis using the JETTO code. The NBI torque is calculated by the PENCIL code. The perpendicular diffusion coefficient and pinch velocity profile are determined by fitting the evolution of the velocity after the switch-off of EFCC current. The TEFCC has a global profile. The maximum torque is in the plasma central region, which is different from the observations on NSTX and DIII-D with higher n perturbation field. This torque is not localized at a certain rational surface and the velocity evolution is obviously different from that in the mode locking phase as also observed on NSTX. With the vacuum field approximation, the NTV torque in the collisionless regime is calculated and compared with the observed TEFCC. The calculated NTV torque profile in the 1/ν regime agrees with the profile of TEFCC, although its absolute value is a factor of 2 larger. The NTV torque in the ν regime from the boundary layer contribution is comparable to the measured torque. Therefore, the NTV torque is in the same order as the observed TEFCC. The NTV torque is a good candidate to explain the non-resonant magnetic braking observed on JET with n=1 perturbation field.

AB - The experimentally measured torque profile of the perturbation field induced by the n=1 EFCC field, TEFCC, is determined by momentum transport analysis using the JETTO code. The NBI torque is calculated by the PENCIL code. The perpendicular diffusion coefficient and pinch velocity profile are determined by fitting the evolution of the velocity after the switch-off of EFCC current. The TEFCC has a global profile. The maximum torque is in the plasma central region, which is different from the observations on NSTX and DIII-D with higher n perturbation field. This torque is not localized at a certain rational surface and the velocity evolution is obviously different from that in the mode locking phase as also observed on NSTX. With the vacuum field approximation, the NTV torque in the collisionless regime is calculated and compared with the observed TEFCC. The calculated NTV torque profile in the 1/ν regime agrees with the profile of TEFCC, although its absolute value is a factor of 2 larger. The NTV torque in the ν regime from the boundary layer contribution is comparable to the measured torque. Therefore, the NTV torque is in the same order as the observed TEFCC. The NTV torque is a good candidate to explain the non-resonant magnetic braking observed on JET with n=1 perturbation field.

UR - https://www.scopus.com/pages/publications/84872737391

M3 - Conference contribution

AN - SCOPUS:84872737391

SN - 9781622763368

T3 - 36th EPS Conference on Plasma Physics 2009, EPS 2009 - Europhysics Conference Abstracts

SP - 41

EP - 44

BT - 36th EPS Conference on Plasma Physics 2009, EPS 2009 - Europhysics Conference Abstracts

T2 - 36th European Physical Society Conference on Plasma Physics 2009, EPS 2009

Y2 - 29 June 2009 through 3 July 2009

ER -

Toroidal rotation braking with low n external perturbation field on JET

Abstract

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