TAE stability calculations compared to TAE antenna results in JET

JET Contributors

doi:10.1088/1741-4326/aabdbd

TAE stability calculations compared to TAE antenna results in JET

JET Contributors

Laboratory for Plasma Physics

Massachusetts Institute of Technology
Culham Centre for Fusion Energy
FORSCHUNGSZENTRUM JULICH GMBH
Institute for Plasma Research
Instituto Superior Técnico
Queens University
University of Helsinki
Commissariat à l'Énergie Atomique (CEA)
VTT Technical Research Centre of Finland
National Institutes for Quantum and Radiological Science and Technology
University of Napoli 'Federico II'
Universidad Nacional de Educación a Distancia
Istituto di Fisica del Plasma Piero Caldirola
ITER
Consorzio Rfx
Kurchatov Institute
University of Napoli Parthenope
ENEA Centro Ricerche Frascati
Troitsk Insitute of Innovating and Thermonuclear Research (TRINITI)
Uppsala University
The National Institute for Cryogenics and Isotopic Technology
Max-Planck-Institut für Plasmaphysik
Università degli Studi di Catania
University of Ghent
Université Libre de Bruxelles
Fusion for Energy
National Institute for Fusion Science
Aalto University
University of Latvia
Imperial College London
Laboratorio Nacional de Fusión
University of Oxford
EUROfusion
Oak Ridge National Laboratory
KARLSRUHER INSTITUT FUER TECHNOLOGIE
University of York
KTH Royal Institute of Technology
Maritime University of Szczecin
Institute of Nuclear Physics PAN
Institute of Plasma Physics, Academy of Sciences of the Czech Republic
University of Trento
Ecole Polytechnique Federale de Lausanne
Wigner Research Centre for Physics
University Mlynska
Lviv Polytechnic National University
University of Milano-Bicocca
The National Institute for Optoelectronics
Fourth State Research
University of Texas at Austin
STUDIECENTRUM VOOR KERNENERGIE / CENTRE D'ETUDE DE L'ENERGIE NUCLEAIRE
Narodowe Centrum Badań Jadrowych
Princeton Plasma Physics Laboratory
Université Aix Marseille
University of Cagliari
University of Warwick
Institute of Plasma Physics and Laser Microfusion
FOM Institute DIFFER
National Institute for Laser, Plasma and Radiation Physics
Jozef Stefan Institute
Université de Lorraine
Institute of Plasma Physics Chinese Academy of Sciences
Center for Energy Research
The 'Horia Hulubei' National Institute for Physics and Nuclear Engineering
Chalmers University of Technology
European Commission
Universidad Politécnica de Madrid
Second University of Napoli
Warsaw University of Technology
University of Basilicata
Barcelona Supercomputer Centre
University of Seville
Centro Brasileiro de Pesquisas Fisicas
University of Rome Tor Vergata
Ioffe Physical-Technical Institute of the Russian Academy of Sciences
General Atomics
Universitat Innsbruck
University of Toyama
University of Strathclyde
National Technical University of Athens
University of Tuscia
Technical University of Denmark
KAIST
Seoul National University
UNIVERSITY COLLEGE CORK, NATIONAL UNIVERSITY OF IRELAND, CORK
Vienna University of Technology
University of Opole
Daegu University
National Fusion Research Institute (NFRI)
Dublin City University
Pelin Llc
Arizona State University
Universidad Complutense de Madrid
University of Basel
Universidad Carlos III de Madrid
Consorzio CREATE
NCSR 'Demokritos'
Purdue University
University of California
Universidade de São Paulo
Lithuanian Energy Institute
HRS Fusion
Politecnico di Torino
University of Cassino
University of Electronic Science and Technology of China

Publikation: Beitrag in Fachzeitschrift › Artikel › Begutachtung

12 Zitate (Scopus)

Abstract

The excitation of modes in the toroidal Alfvén eigenmodes (TAE) gap by an external antenna can be modelled by a driven damped harmonic oscillator. By performing a frequency scan it is possible to determine the damping rate of the mode through the quality factor. This method has been employed in recent Joint European Torus (JET) experiments dedicated to scenario development for the observation of alpha-driven instabilities in JET DT plasmas (i.e. plasmas composed by Deuterium and Tritium). However, the toroidal mode number n of the mode for which the measurements were performed could not be determined experimentally. The value of the damping obtained through experimental measurements for a selected time slice is then compared with those obtained from calculations performed by numerical codes for different modes with frequencies close to the experimental frequency of the antenna. This paper describes the modelling method and presents the numerical simulations carried out using a suite of codes to calculate the damping of TAE, which are compared with the value measured experimentally. The radial structures of these modes are first calculated with the ideal magnetohydrodynamic (MHD) code MISHKA. For each of these modes, the damping on thermal ions and thermal electrons and the contribution to the mode growth rate resulting from the resonant interaction with the ion cyclotron resonance heating (ICRH) accelerated ion population are calculated using the drift-kinetic code CASTOR-K. The radiative damping is calculated by using a complex resistivity in the resistive MHD code CASTOR code and the continuum damping is estimated using also the CASTOR code through the standard method of making the real part of the resistivity tend to zero. It was found the radiative damping is largely dominant over all other effects, except for the n = 3 TAE. The overall damping calculated numerically is consistent with the damping measured experimentally.

Originalsprache	Englisch
Aufsatznummer	082007
Fachzeitschrift	Nuclear Fusion
Jahrgang	58
Ausgabenummer	8
DOIs	https://doi.org/10.1088/1741-4326/aabdbd
Publikationsstatus	Veröffentlicht - 29 Juni 2018

Zugriff auf Dokument

10.1088/1741-4326/aabdbd

Andere Dateien und Links

Verknüpfung zur Publikation in Scopus

Dieses zitieren

@article{7138f3613b164c17905194ae6730ed98,

title = "TAE stability calculations compared to TAE antenna results in JET",

abstract = "The excitation of modes in the toroidal Alfv{\'e}n eigenmodes (TAE) gap by an external antenna can be modelled by a driven damped harmonic oscillator. By performing a frequency scan it is possible to determine the damping rate of the mode through the quality factor. This method has been employed in recent Joint European Torus (JET) experiments dedicated to scenario development for the observation of alpha-driven instabilities in JET DT plasmas (i.e. plasmas composed by Deuterium and Tritium). However, the toroidal mode number n of the mode for which the measurements were performed could not be determined experimentally. The value of the damping obtained through experimental measurements for a selected time slice is then compared with those obtained from calculations performed by numerical codes for different modes with frequencies close to the experimental frequency of the antenna. This paper describes the modelling method and presents the numerical simulations carried out using a suite of codes to calculate the damping of TAE, which are compared with the value measured experimentally. The radial structures of these modes are first calculated with the ideal magnetohydrodynamic (MHD) code MISHKA. For each of these modes, the damping on thermal ions and thermal electrons and the contribution to the mode growth rate resulting from the resonant interaction with the ion cyclotron resonance heating (ICRH) accelerated ion population are calculated using the drift-kinetic code CASTOR-K. The radiative damping is calculated by using a complex resistivity in the resistive MHD code CASTOR code and the continuum damping is estimated using also the CASTOR code through the standard method of making the real part of the resistivity tend to zero. It was found the radiative damping is largely dominant over all other effects, except for the n = 3 TAE. The overall damping calculated numerically is consistent with the damping measured experimentally.",

keywords = "Alfv{\'e}n eigemodes, TAE antenna, energetic particles, tokamaks",

author = "M. Porkolab and X. Litaudon and S. Abduallev and M. Abhangi and P. Abreu and M. Afzal and Aggarwal, \{K. M.\} and T. Ahlgren and Ahn, \{J. H.\} and L. Aho-Mantila and N. Aiba and M. Airila and R. Albanese and V. Aldred and D. Alegre and E. Alessi and P. Aleynikov and A. Alfier and A. Alkseev and M. Allinson and B. Alper and E. Alves and G. Ambrosino and R. Ambrosino and L. Amicucci and V. Amosov and Sund{\'e}n, \{E. Andersson\} and M. Angelone and M. Anghel and C. Angioni and L. Appel and C. Appelbee and P. Arena and M. Ariola and K. Cromb{\'e} and P. Dumortier and F. Durodi{\'e} and S. Jachmich and Y. Kazakov and A. Krivska and E. Lerche and A. Lyssoivan and A. Messiaen and S. Moradi and J. Ongena and R. Ragona and I. Stepanov and \{van Eester\}, D. and G. Verdoolaege and T. Wauters and \{JET Contributors\}",

note = "Publisher Copyright: {\textcopyright} EURATOM 2018.",

year = "2018",

month = jun,

day = "29",

doi = "10.1088/1741-4326/aabdbd",

language = "English",

volume = "58",

journal = "Nuclear Fusion",

issn = "0029-5515",

number = "8",

}

TY - JOUR

T1 - TAE stability calculations compared to TAE antenna results in JET

AU - Porkolab, M.

AU - Litaudon, X.

AU - Abduallev, S.

AU - Abhangi, M.

AU - Abreu, P.

AU - Afzal, M.

AU - Aggarwal, K. M.

AU - Ahlgren, T.

AU - Ahn, J. H.

AU - Aho-Mantila, L.

AU - Aiba, N.

AU - Airila, M.

AU - Albanese, R.

AU - Aldred, V.

AU - Alegre, D.

AU - Alessi, E.

AU - Aleynikov, P.

AU - Alfier, A.

AU - Alkseev, A.

AU - Allinson, M.

AU - Alper, B.

AU - Alves, E.

AU - Ambrosino, G.

AU - Ambrosino, R.

AU - Amicucci, L.

AU - Amosov, V.

AU - Sundén, E. Andersson

AU - Angelone, M.

AU - Anghel, M.

AU - Angioni, C.

AU - Appel, L.

AU - Appelbee, C.

AU - Arena, P.

AU - Ariola, M.

AU - Crombé, K.

AU - Dumortier, P.

AU - Durodié, F.

AU - Jachmich, S.

AU - Kazakov, Y.

AU - Krivska, A.

AU - Lerche, E.

AU - Lyssoivan, A.

AU - Messiaen, A.

AU - Moradi, S.

AU - Ongena, J.

AU - Ragona, R.

AU - Stepanov, I.

AU - van Eester, D.

AU - Verdoolaege, G.

AU - Wauters, T.

AU - JET Contributors

PY - 2018/6/29

Y1 - 2018/6/29

N2 - The excitation of modes in the toroidal Alfvén eigenmodes (TAE) gap by an external antenna can be modelled by a driven damped harmonic oscillator. By performing a frequency scan it is possible to determine the damping rate of the mode through the quality factor. This method has been employed in recent Joint European Torus (JET) experiments dedicated to scenario development for the observation of alpha-driven instabilities in JET DT plasmas (i.e. plasmas composed by Deuterium and Tritium). However, the toroidal mode number n of the mode for which the measurements were performed could not be determined experimentally. The value of the damping obtained through experimental measurements for a selected time slice is then compared with those obtained from calculations performed by numerical codes for different modes with frequencies close to the experimental frequency of the antenna. This paper describes the modelling method and presents the numerical simulations carried out using a suite of codes to calculate the damping of TAE, which are compared with the value measured experimentally. The radial structures of these modes are first calculated with the ideal magnetohydrodynamic (MHD) code MISHKA. For each of these modes, the damping on thermal ions and thermal electrons and the contribution to the mode growth rate resulting from the resonant interaction with the ion cyclotron resonance heating (ICRH) accelerated ion population are calculated using the drift-kinetic code CASTOR-K. The radiative damping is calculated by using a complex resistivity in the resistive MHD code CASTOR code and the continuum damping is estimated using also the CASTOR code through the standard method of making the real part of the resistivity tend to zero. It was found the radiative damping is largely dominant over all other effects, except for the n = 3 TAE. The overall damping calculated numerically is consistent with the damping measured experimentally.

AB - The excitation of modes in the toroidal Alfvén eigenmodes (TAE) gap by an external antenna can be modelled by a driven damped harmonic oscillator. By performing a frequency scan it is possible to determine the damping rate of the mode through the quality factor. This method has been employed in recent Joint European Torus (JET) experiments dedicated to scenario development for the observation of alpha-driven instabilities in JET DT plasmas (i.e. plasmas composed by Deuterium and Tritium). However, the toroidal mode number n of the mode for which the measurements were performed could not be determined experimentally. The value of the damping obtained through experimental measurements for a selected time slice is then compared with those obtained from calculations performed by numerical codes for different modes with frequencies close to the experimental frequency of the antenna. This paper describes the modelling method and presents the numerical simulations carried out using a suite of codes to calculate the damping of TAE, which are compared with the value measured experimentally. The radial structures of these modes are first calculated with the ideal magnetohydrodynamic (MHD) code MISHKA. For each of these modes, the damping on thermal ions and thermal electrons and the contribution to the mode growth rate resulting from the resonant interaction with the ion cyclotron resonance heating (ICRH) accelerated ion population are calculated using the drift-kinetic code CASTOR-K. The radiative damping is calculated by using a complex resistivity in the resistive MHD code CASTOR code and the continuum damping is estimated using also the CASTOR code through the standard method of making the real part of the resistivity tend to zero. It was found the radiative damping is largely dominant over all other effects, except for the n = 3 TAE. The overall damping calculated numerically is consistent with the damping measured experimentally.

KW - Alfvén eigemodes

KW - TAE antenna

KW - energetic particles

KW - tokamaks

UR - https://www.scopus.com/pages/publications/85050380018

U2 - 10.1088/1741-4326/aabdbd

DO - 10.1088/1741-4326/aabdbd

M3 - Article

AN - SCOPUS:85050380018

SN - 0029-5515

VL - 58

JO - Nuclear Fusion

JF - Nuclear Fusion

IS - 8

M1 - 082007

ER -

TAE stability calculations compared to TAE antenna results in JET

Abstract

Zugriff auf Dokument

Andere Dateien und Links

Fingerprint

Dieses zitieren