Designing the IShTAR antenna: Physics and engineering aspects

F. Louche; J. Jacquot; K. Crombé; D. Van Eester; R. D'Inca; S. Devaux; E. Faudot; H. Faugel; H. Fünfgelder; S. Heuraux; I. Morgal; J. Moritz; R. Ochoukov; J. M. Noterdaeme

doi:10.1063/1.4936523

Designing the IShTAR antenna: Physics and engineering aspects

F. Louche, J. Jacquot, K. Crombé, D. Van Eester, R. D'Inca, S. Devaux, E. Faudot, H. Faugel, H. Fünfgelder, S. Heuraux, I. Morgal, J. Moritz, R. Ochoukov, J. M. Noterdaeme

Laboratory for Plasma Physics

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

Abstract

IShTAR (Ion cyclotron Sheath Test ARrangement) is a magnetised plasma test facility installed at the Max-Planck-Institut für Plasmaphysik in Garching, Germany. The main purpose of this device is the study of RF sheaths generated in front of ICRF (Ion Cyclotron Range of Frequency) antennas in magnetically confined plasmas. The plasma is generated by a helical RF antenna potentially able to reach a helicon mode. We present in this work recent modelling activities dedicated to IShTAR. On the one hand a parameterized magnetostatic model of the magnetic configuration was created with the finite element solver COMSOL Multiphysics [3]. The model considers two non-axial sets of coils and notably reproduces the magnetic field lines deviation at the center of the main vessel and the ripples observed during experiments. From this model we can infer that 2.4 kA are required in the 2 main large coils of IShTAR for 1 kA in the 4 small coils to generate a "smooth" magnetic field along field lines. On the other hand an ICRF antenna has been designed for IShTAR. A tridimensional model of the IShTAR vessel was developed with the electromagnetic code MicroWave Studio (MWS [4]) for this purpose and a first antenna model made of a single strap inside a box was included. The strap is fed through the upper port located at the helicon source side. The antenna is fully immersed into the loading medium (plasma or homogeneous dielectric) and the curved strap front face is aligned with the magnetic surfaces to simplify the modelling. The initial design of this antenna has been studied with MWS in the presence of homogeneous dielectric. The presence of a back wall will be discussed.

Originalsprache	Englisch
Titel	Radio Frequency Power in Plasmas
Untertitel	Proceedings of the 21St Topical Conference
Redakteure/-innen	Robert I. Pinsker
Herausgeber (Verlag)	American Institute of Physics Inc.
ISBN (elektronisch)	9780735413368
DOIs	https://doi.org/10.1063/1.4936523
Publikationsstatus	Veröffentlicht - 10 Dez. 2015
Veranstaltung	21st Topical Conference on Radiofrequency Power in Plasmas - Lake Arrowhead, USA/Vereinigte Staaten Dauer: 27 Apr. 2015 → 29 Apr. 2015

Publikationsreihe

Name	AIP Conference Proceedings
Band	1689
ISSN (Print)	0094-243X
ISSN (elektronisch)	1551-7616

Konferenz

Konferenz	21st Topical Conference on Radiofrequency Power in Plasmas
Land/Gebiet	USA/Vereinigte Staaten
Ort	Lake Arrowhead
Zeitraum	27/04/15 → 29/04/15

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Louche, F., Jacquot, J., Crombé, K., Van Eester, D., D'Inca, R., Devaux, S., Faudot, E., Faugel, H., Fünfgelder, H., Heuraux, S., Morgal, I., Moritz, J., Ochoukov, R., & Noterdaeme, J. M. (2015). Designing the IShTAR antenna: Physics and engineering aspects. in R. I. Pinsker (Hrsg.), Radio Frequency Power in Plasmas: Proceedings of the 21St Topical Conference Artikel 070016 (AIP Conference Proceedings; Band 1689). American Institute of Physics Inc.. https://doi.org/10.1063/1.4936523

@inproceedings{34201bc24d454f97bd4c48deb8f7f0b1,

title = "Designing the IShTAR antenna: Physics and engineering aspects",

abstract = "IShTAR (Ion cyclotron Sheath Test ARrangement) is a magnetised plasma test facility installed at the Max-Planck-Institut f{\"u}r Plasmaphysik in Garching, Germany. The main purpose of this device is the study of RF sheaths generated in front of ICRF (Ion Cyclotron Range of Frequency) antennas in magnetically confined plasmas. The plasma is generated by a helical RF antenna potentially able to reach a helicon mode. We present in this work recent modelling activities dedicated to IShTAR. On the one hand a parameterized magnetostatic model of the magnetic configuration was created with the finite element solver COMSOL Multiphysics [3]. The model considers two non-axial sets of coils and notably reproduces the magnetic field lines deviation at the center of the main vessel and the ripples observed during experiments. From this model we can infer that 2.4 kA are required in the 2 main large coils of IShTAR for 1 kA in the 4 small coils to generate a {"}smooth{"} magnetic field along field lines. On the other hand an ICRF antenna has been designed for IShTAR. A tridimensional model of the IShTAR vessel was developed with the electromagnetic code MicroWave Studio (MWS [4]) for this purpose and a first antenna model made of a single strap inside a box was included. The strap is fed through the upper port located at the helicon source side. The antenna is fully immersed into the loading medium (plasma or homogeneous dielectric) and the curved strap front face is aligned with the magnetic surfaces to simplify the modelling. The initial design of this antenna has been studied with MWS in the presence of homogeneous dielectric. The presence of a back wall will be discussed.",

author = "F. Louche and J. Jacquot and K. Cromb{\'e} and {Van Eester}, D. and R. D'Inca and S. Devaux and E. Faudot and H. Faugel and H. F{\"u}nfgelder and S. Heuraux and I. Morgal and J. Moritz and R. Ochoukov and Noterdaeme, {J. M.}",

note = "Funding Information: This work has been carried out within the framework of the EUROfusion Consortium and has received funding from the Euratom research and training programme 2014-2018 under grant agreement No 633053. The views and opinions expressed herein do not necessarily reflect those of the European Commission.; 21st Topical Conference on Radiofrequency Power in Plasmas ; Conference date: 27-04-2015 Through 29-04-2015",

year = "2015",

month = dec,

day = "10",

doi = "10.1063/1.4936523",

language = "English",

series = "AIP Conference Proceedings",

publisher = "American Institute of Physics Inc.",

editor = "Pinsker, {Robert I.}",

booktitle = "Radio Frequency Power in Plasmas",

}

Louche, F, Jacquot, J, Crombé, K , Van Eester, D, D'Inca, R, Devaux, S, Faudot, E, Faugel, H, Fünfgelder, H, Heuraux, S, Morgal, I, Moritz, J, Ochoukov, R & Noterdaeme, JM 2015, Designing the IShTAR antenna: Physics and engineering aspects. in RI Pinsker (Hrsg.), Radio Frequency Power in Plasmas: Proceedings of the 21St Topical Conference., 070016, AIP Conference Proceedings, Bd. 1689, American Institute of Physics Inc., 21st Topical Conference on Radiofrequency Power in Plasmas, Lake Arrowhead, USA/Vereinigte Staaten, 27/04/15. https://doi.org/10.1063/1.4936523

Designing the IShTAR antenna: Physics and engineering aspects. / Louche, F.; Jacquot, J.; Crombé, K. et al.
Radio Frequency Power in Plasmas: Proceedings of the 21St Topical Conference. Hrsg. / Robert I. Pinsker. American Institute of Physics Inc., 2015. 070016 (AIP Conference Proceedings; Band 1689).

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

TY - GEN

T1 - Designing the IShTAR antenna

T2 - 21st Topical Conference on Radiofrequency Power in Plasmas

AU - Louche, F.

AU - Jacquot, J.

AU - Crombé, K.

AU - Van Eester, D.

AU - D'Inca, R.

AU - Devaux, S.

AU - Faudot, E.

AU - Faugel, H.

AU - Fünfgelder, H.

AU - Heuraux, S.

AU - Morgal, I.

AU - Moritz, J.

AU - Ochoukov, R.

AU - Noterdaeme, J. M.

N1 - Funding Information: This work has been carried out within the framework of the EUROfusion Consortium and has received funding from the Euratom research and training programme 2014-2018 under grant agreement No 633053. The views and opinions expressed herein do not necessarily reflect those of the European Commission.

PY - 2015/12/10

Y1 - 2015/12/10

N2 - IShTAR (Ion cyclotron Sheath Test ARrangement) is a magnetised plasma test facility installed at the Max-Planck-Institut für Plasmaphysik in Garching, Germany. The main purpose of this device is the study of RF sheaths generated in front of ICRF (Ion Cyclotron Range of Frequency) antennas in magnetically confined plasmas. The plasma is generated by a helical RF antenna potentially able to reach a helicon mode. We present in this work recent modelling activities dedicated to IShTAR. On the one hand a parameterized magnetostatic model of the magnetic configuration was created with the finite element solver COMSOL Multiphysics [3]. The model considers two non-axial sets of coils and notably reproduces the magnetic field lines deviation at the center of the main vessel and the ripples observed during experiments. From this model we can infer that 2.4 kA are required in the 2 main large coils of IShTAR for 1 kA in the 4 small coils to generate a "smooth" magnetic field along field lines. On the other hand an ICRF antenna has been designed for IShTAR. A tridimensional model of the IShTAR vessel was developed with the electromagnetic code MicroWave Studio (MWS [4]) for this purpose and a first antenna model made of a single strap inside a box was included. The strap is fed through the upper port located at the helicon source side. The antenna is fully immersed into the loading medium (plasma or homogeneous dielectric) and the curved strap front face is aligned with the magnetic surfaces to simplify the modelling. The initial design of this antenna has been studied with MWS in the presence of homogeneous dielectric. The presence of a back wall will be discussed.

AB - IShTAR (Ion cyclotron Sheath Test ARrangement) is a magnetised plasma test facility installed at the Max-Planck-Institut für Plasmaphysik in Garching, Germany. The main purpose of this device is the study of RF sheaths generated in front of ICRF (Ion Cyclotron Range of Frequency) antennas in magnetically confined plasmas. The plasma is generated by a helical RF antenna potentially able to reach a helicon mode. We present in this work recent modelling activities dedicated to IShTAR. On the one hand a parameterized magnetostatic model of the magnetic configuration was created with the finite element solver COMSOL Multiphysics [3]. The model considers two non-axial sets of coils and notably reproduces the magnetic field lines deviation at the center of the main vessel and the ripples observed during experiments. From this model we can infer that 2.4 kA are required in the 2 main large coils of IShTAR for 1 kA in the 4 small coils to generate a "smooth" magnetic field along field lines. On the other hand an ICRF antenna has been designed for IShTAR. A tridimensional model of the IShTAR vessel was developed with the electromagnetic code MicroWave Studio (MWS [4]) for this purpose and a first antenna model made of a single strap inside a box was included. The strap is fed through the upper port located at the helicon source side. The antenna is fully immersed into the loading medium (plasma or homogeneous dielectric) and the curved strap front face is aligned with the magnetic surfaces to simplify the modelling. The initial design of this antenna has been studied with MWS in the presence of homogeneous dielectric. The presence of a back wall will be discussed.

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U2 - 10.1063/1.4936523

DO - 10.1063/1.4936523

M3 - Conference contribution

AN - SCOPUS:84984539137

T3 - AIP Conference Proceedings

BT - Radio Frequency Power in Plasmas

A2 - Pinsker, Robert I.

PB - American Institute of Physics Inc.

Y2 - 27 April 2015 through 29 April 2015

ER -

Designing the IShTAR antenna: Physics and engineering aspects

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