Application of ICRF waves in tokamaks beyond heating

M. J. Mantsinen; L. G. Eriksson; E. Gauthier; G. T. Hoang; E. Joffrin; R. Koch; X. Litaudon; A. Lyssoivan; P. Mantica; M. F.F. Nave; J. M. Noterdaeme; C. C. Petty; O. Sauter; S. E. Sharapov

doi:10.1088/0741-3335/45/12A/028

Application of ICRF waves in tokamaks beyond heating

M. J. Mantsinen
, L. G. Eriksson
, E. Gauthier
, G. T. Hoang
, E. Joffrin
, R. Koch
, X. Litaudon
, A. Lyssoivan
, P. Mantica
, M. F.F. Nave
, J. M. Noterdaeme
, C. C. Petty
, O. Sauter
, S. E. Sharapov

Laboratory for Plasma Physics

Aalto University
Commissariat à l'Énergie Atomique (CEA)
Associazione EURATOM-ENEA sulla Fusione
Instituto Superior Técnico
Max-Planck-Institut für Plasmaphysik
University of Ghent
General Atomics
Ecole Polytechnique Federale de Lausanne
Culham Centre for Fusion Energy

Publikation: Beitrag in Fachzeitschrift › Artikel › Begutachtung

38 Zitate (Scopus)

Abstract

Interaction of waves in the ion cyclotron range of frequencies (ICRF) with a plasma has a number of key properties that make them attractive beyond pure heating. First, the waves can interact resonantly with either the plasma ions or electrons. In the case of ion cyclotron damping, a small number of resonant ions are often accelerated to high energies. These ions, apart from heating the bulk plasma via Coulomb collisions, can increase fusion reactivity, affect plasma stability and drive current. They have also been invaluable in diagnostic applications and simulations of fusion-born 3.5 MeV alpha-particles. The second key property of ICRF waves is the transfer of wave momentum to the plasma. This allows one to drive current, affect plasma rotation and induce radial transport of the fast-ions with toroidally directed waves. Finally, ICRF power deposition is rather narrow and its location can be externally controlled, which has important applications in improving the plasma performance, affecting the local plasma transport and providing a tool for plasma transport studies. Representative examples from present-day tokamak experiments are reviewed to highlight the available capabilities.

Originalsprache	Englisch
Seiten (von - bis)	A445-A456
Fachzeitschrift	Plasma Physics and Controlled Fusion
Jahrgang	45
Ausgabenummer	12 A
DOIs	https://doi.org/10.1088/0741-3335/45/12A/028
Publikationsstatus	Veröffentlicht - Dez. 2003

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Mantsinen, M. J., Eriksson, L. G., Gauthier, E., Hoang, G. T., Joffrin, E., Koch, R., Litaudon, X., Lyssoivan, A., Mantica, P., Nave, M. F. F., Noterdaeme, J. M., Petty, C. C., Sauter, O., & Sharapov, S. E. (2003). Application of ICRF waves in tokamaks beyond heating. Plasma Physics and Controlled Fusion, 45(12 A), A445-A456. https://doi.org/10.1088/0741-3335/45/12A/028

@article{091774dfc0d644d1970619af6217a46a,

title = "Application of ICRF waves in tokamaks beyond heating",

abstract = "Interaction of waves in the ion cyclotron range of frequencies (ICRF) with a plasma has a number of key properties that make them attractive beyond pure heating. First, the waves can interact resonantly with either the plasma ions or electrons. In the case of ion cyclotron damping, a small number of resonant ions are often accelerated to high energies. These ions, apart from heating the bulk plasma via Coulomb collisions, can increase fusion reactivity, affect plasma stability and drive current. They have also been invaluable in diagnostic applications and simulations of fusion-born 3.5 MeV alpha-particles. The second key property of ICRF waves is the transfer of wave momentum to the plasma. This allows one to drive current, affect plasma rotation and induce radial transport of the fast-ions with toroidally directed waves. Finally, ICRF power deposition is rather narrow and its location can be externally controlled, which has important applications in improving the plasma performance, affecting the local plasma transport and providing a tool for plasma transport studies. Representative examples from present-day tokamak experiments are reviewed to highlight the available capabilities.",

author = "Mantsinen, \{M. J.\} and Eriksson, \{L. G.\} and E. Gauthier and Hoang, \{G. T.\} and E. Joffrin and R. Koch and X. Litaudon and A. Lyssoivan and P. Mantica and Nave, \{M. F.F.\} and Noterdaeme, \{J. M.\} and Petty, \{C. C.\} and O. Sauter and Sharapov, \{S. E.\}",

year = "2003",

month = dec,

doi = "10.1088/0741-3335/45/12A/028",

language = "English",

volume = "45",

pages = "A445--A456",

journal = "Plasma Physics and Controlled Fusion",

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AU - Mantsinen, M. J.

AU - Eriksson, L. G.

AU - Gauthier, E.

AU - Hoang, G. T.

AU - Joffrin, E.

AU - Koch, R.

AU - Litaudon, X.

AU - Lyssoivan, A.

AU - Mantica, P.

AU - Nave, M. F.F.

AU - Noterdaeme, J. M.

AU - Petty, C. C.

AU - Sauter, O.

AU - Sharapov, S. E.

PY - 2003/12

Y1 - 2003/12

N2 - Interaction of waves in the ion cyclotron range of frequencies (ICRF) with a plasma has a number of key properties that make them attractive beyond pure heating. First, the waves can interact resonantly with either the plasma ions or electrons. In the case of ion cyclotron damping, a small number of resonant ions are often accelerated to high energies. These ions, apart from heating the bulk plasma via Coulomb collisions, can increase fusion reactivity, affect plasma stability and drive current. They have also been invaluable in diagnostic applications and simulations of fusion-born 3.5 MeV alpha-particles. The second key property of ICRF waves is the transfer of wave momentum to the plasma. This allows one to drive current, affect plasma rotation and induce radial transport of the fast-ions with toroidally directed waves. Finally, ICRF power deposition is rather narrow and its location can be externally controlled, which has important applications in improving the plasma performance, affecting the local plasma transport and providing a tool for plasma transport studies. Representative examples from present-day tokamak experiments are reviewed to highlight the available capabilities.

AB - Interaction of waves in the ion cyclotron range of frequencies (ICRF) with a plasma has a number of key properties that make them attractive beyond pure heating. First, the waves can interact resonantly with either the plasma ions or electrons. In the case of ion cyclotron damping, a small number of resonant ions are often accelerated to high energies. These ions, apart from heating the bulk plasma via Coulomb collisions, can increase fusion reactivity, affect plasma stability and drive current. They have also been invaluable in diagnostic applications and simulations of fusion-born 3.5 MeV alpha-particles. The second key property of ICRF waves is the transfer of wave momentum to the plasma. This allows one to drive current, affect plasma rotation and induce radial transport of the fast-ions with toroidally directed waves. Finally, ICRF power deposition is rather narrow and its location can be externally controlled, which has important applications in improving the plasma performance, affecting the local plasma transport and providing a tool for plasma transport studies. Representative examples from present-day tokamak experiments are reviewed to highlight the available capabilities.

UR - https://www.scopus.com/pages/publications/9144228747

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DO - 10.1088/0741-3335/45/12A/028

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AN - SCOPUS:9144228747

SN - 0741-3335

VL - 45

SP - A445-A456

JO - Plasma Physics and Controlled Fusion

JF - Plasma Physics and Controlled Fusion

IS - 12 A

ER -

Application of ICRF waves in tokamaks beyond heating

Abstract

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