Modelling of JET hybrid plasmas with emphasis on performance of combined ICRF and NBI heating

JET Contributors

doi:10.1088/1741-4326/aad9ad

Modelling of JET hybrid plasmas with emphasis on performance of combined ICRF and NBI heating

JET Contributors

Earth Sciences
Pompeu Fabra University (UPF)
Culham Centre for Fusion Energy
ENEA Centro Ricerche Frascati
EURATOM Assoc.
ENAC-IIC-GEL
Max-Planck-Institut für Plasmaphysik
Soltan Institute for Nuclear Studies
Uppsala University
CEA Cadarache
CEA/UVSQ/CNRS
European Commission
Koninklijke Militaire School - Ecole Royale Militaire
Opole University
FOM Institute DIFFER 'Dutch Institute for Fundamental Energy Research'
Association EURATOM-FOM
KTH Royal Institute of Technology
Consorzio Rfx
Culham Science Centre
Research Centre Julich
Institute for Plasma Research
Instituto Superior Técnico
Queen's University of Belfast
University of Helsinki
VTT Technical Research Centre of Finland Ltd
National Institutes for Quantum and Radiological Science and Technology
University of Naples Federico II
Universidad Nacional de Educación a Distancia
IFP-CNR
ITER
Kurchatov Institute
Università di Napoli Parthenope
Troitsk Insitute of Innovating and Thermonuclear Research (TRINITI)
National Institute for Cryogenics and Isotopic Technology
Università degli Studi di Catania
Fusion for Energy
National Institute for Fusion Science
Massachusetts Institute of Technology
Aalto University
University of Latvia (LU)
Imperial College London
Laboratorio Nacional de Fusión
University of Oxford
EUROfusion Programme Management Unit
Oak Ridge National Laboratory
Institute of Meteorology and Climate Research
University of York
Teilinsitut Greifswald
Maritime University of Szczecin
Institute for Nuclear Physics
Institute of Plasma Physics AS CR
Università di Trento
Wigner Research Centre for Physics
Comenius University
Lviv Polytechnic National University
University of Milano-Bicocca
National Institute for Optoelectronics
Fourth State Research
The University of Texas at Austin
Nuclear Research Centre
National Centre for Nuclear Research
Princeton Plasma Physics Laboratory
Aix-Marseille Université
Universitá di Cagliari
University of Warwick
Plasma and Radiation Physics (INFLPR)
Ghent University
Department of Biochemistry and Molecular and Structural Biology
Univ.́ Henri Poincaré
Institute of Plasma Physics, Chinese Academy of Sciences
Center for Energy Research
Horia Hulubei National Institute of Physics and Nuclear Engineering
Chalmers University of Technology
Universidad Politécnica de Madrid
University of Campania L. Vanvitelli
Warsaw University of Technology
Università degli Studi della Basilicata
Aix Marseille Université
University of Seville
Centro Brasileiro de Pesquisas Fisicas
IUSTI
University of Rome “Tor Vergata”
Ioffe Institute
General Atomics
University of Innsbruck
University of Toyama
University of Strathclyde
National Technical University of Athens
Tuscia University
Technical University of Denmark
Korea Advanced Institute of Science and Technology
Seoul National University
University College Cork
Vienna University of Technology
Daegu University
National Fusion Research Institute
Dublin City University
PELIN LLC
Arizona State University
Complutense University
University of Basel
Universidad Carlos III de Madrid
Consorzio CREATE
NCSR Demokritos
Purdue University
ULB-Campus Plaine
University of California
University of São Paulo
Lithuanian Energy Institute
HRS Fusion
Politecnico di Torino
Università di Cassino
Medical School of UESTC

Résultats de recherche: Contribution à un journal › Article › Revue par des pairs

Résumé

During the 2015-2016 JET campaigns, many efforts have been devoted to the exploration of high-performance plasma scenarios envisaged for DT operation in JET. In this paper, we review various key recent hybrid discharges and model the combined ICRF+NBI heating. These deuterium discharges with deuterium beams had the ICRF antenna frequency tuned to match the cyclotron frequency of minority H at the centre of the tokamak coinciding with the second harmonic cyclotron resonance of D. The modelling takes into account the synergy between ICRF and NBI heating through the second harmonic cyclotron resonance of D beam ions, allowing us to assess its impact on the neutron rate R _NT. For discharges carried out with a fixed ICRF antenna frequency and changing toroidal magnetic field to vary the resonance position, we evaluate the influence of the resonance position on the heating performance and central impurity control. The H concentration is varied between discharges in order to test its role in the heating performance. It is found that discharges with a resonance beyond ∼0.15 m from the magnetic axis R ₀ suffer from MHD activity and impurity accumulation in these plasma conditions. According to our modelling, the ICRF enhancement of R _NT increases with the ICRF power absorbed by deuterons as the H concentration decreases. We find that in the recent hybrid discharges, this ICRF enhancement varies due to a variation of H concentration and is in the range of 10%-25%. The modelling of a recent record high-performance hybrid discharge shows that ICRF fusion yield enhancement of ∼30% and ∼15% respectively can be achieved in the ramp-up phase and during the main heating phase. We extrapolate the results to DT and find that the best performing hybrid discharges correspond to an equivalent fusion power of ∼7.0 MW in DT. Finally, an optimization analysis of the bulk ion heating for the DT scenario reveals around 15%-20% larger bulk ion heating for the ³He minority scenario as compared to the H minority scenario.

langue originale	Anglais
Numéro d'article	106037
journal	Nuclear Fusion
Volume	58
Numéro de publication	10
Les DOIs	https://doi.org/10.1088/1741-4326/aad9ad
état	Publié - 5 sept. 2018
Modification externe	Oui

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10.1088/1741-4326/aad9ad

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@article{1f470c3f359e4ba98725fa7fc1e982f7,

title = "Modelling of JET hybrid plasmas with emphasis on performance of combined ICRF and NBI heating",

abstract = "During the 2015-2016 JET campaigns, many efforts have been devoted to the exploration of high-performance plasma scenarios envisaged for DT operation in JET. In this paper, we review various key recent hybrid discharges and model the combined ICRF+NBI heating. These deuterium discharges with deuterium beams had the ICRF antenna frequency tuned to match the cyclotron frequency of minority H at the centre of the tokamak coinciding with the second harmonic cyclotron resonance of D. The modelling takes into account the synergy between ICRF and NBI heating through the second harmonic cyclotron resonance of D beam ions, allowing us to assess its impact on the neutron rate R NT. For discharges carried out with a fixed ICRF antenna frequency and changing toroidal magnetic field to vary the resonance position, we evaluate the influence of the resonance position on the heating performance and central impurity control. The H concentration is varied between discharges in order to test its role in the heating performance. It is found that discharges with a resonance beyond ∼0.15 m from the magnetic axis R 0 suffer from MHD activity and impurity accumulation in these plasma conditions. According to our modelling, the ICRF enhancement of R NT increases with the ICRF power absorbed by deuterons as the H concentration decreases. We find that in the recent hybrid discharges, this ICRF enhancement varies due to a variation of H concentration and is in the range of 10\%-25\%. The modelling of a recent record high-performance hybrid discharge shows that ICRF fusion yield enhancement of ∼30\% and ∼15\% respectively can be achieved in the ramp-up phase and during the main heating phase. We extrapolate the results to DT and find that the best performing hybrid discharges correspond to an equivalent fusion power of ∼7.0 MW in DT. Finally, an optimization analysis of the bulk ion heating for the DT scenario reveals around 15\%-20\% larger bulk ion heating for the 3He minority scenario as compared to the H minority scenario.",

keywords = "ICRF heating, JET hybrid plasmas, NBI heating, fusion enhancement",

author = "\{JET Contributors\} and D. Gallart and Mantsinen, \{M. J.\} and C. Challis and D. Frigione and J. Graves and E. Belonohy and F. Casson and A. Czarnecka and J. Eriksson and J. Garcia and M. Goniche and C. Hellesen and J. Hobirk and P. Jaquet and E. Joffrin and N. Krawczyk and D. King and M. Lennholm and E. Lerche and E. Pawelec and X. S{\'a}ez and M. Sertoli and G. Sips and M. Tsalas and P. Vallejos and M. Valisa 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. Alfer and A. Alkseev and M. Allinson and B. Alper and E. Alves and G. Ambrosino and R. Ambrosino and T. Nicolas",

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

year = "2018",

month = sep,

day = "5",

doi = "10.1088/1741-4326/aad9ad",

language = "English",

volume = "58",

journal = "Nuclear Fusion",

issn = "0029-5515",

number = "10",

}

TY - JOUR

T1 - Modelling of JET hybrid plasmas with emphasis on performance of combined ICRF and NBI heating

AU - JET Contributors

AU - Gallart, D.

AU - Mantsinen, M. J.

AU - Challis, C.

AU - Frigione, D.

AU - Graves, J.

AU - Belonohy, E.

AU - Casson, F.

AU - Czarnecka, A.

AU - Eriksson, J.

AU - Garcia, J.

AU - Goniche, M.

AU - Hellesen, C.

AU - Hobirk, J.

AU - Jaquet, P.

AU - Joffrin, E.

AU - Krawczyk, N.

AU - King, D.

AU - Lennholm, M.

AU - Lerche, E.

AU - Pawelec, E.

AU - Sáez, X.

AU - Sertoli, M.

AU - Sips, G.

AU - Tsalas, M.

AU - Vallejos, P.

AU - Valisa, 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 - Alfer, A.

AU - Alkseev, A.

AU - Allinson, M.

AU - Alper, B.

AU - Alves, E.

AU - Ambrosino, G.

AU - Ambrosino, R.

AU - Nicolas, T.

PY - 2018/9/5

Y1 - 2018/9/5

N2 - During the 2015-2016 JET campaigns, many efforts have been devoted to the exploration of high-performance plasma scenarios envisaged for DT operation in JET. In this paper, we review various key recent hybrid discharges and model the combined ICRF+NBI heating. These deuterium discharges with deuterium beams had the ICRF antenna frequency tuned to match the cyclotron frequency of minority H at the centre of the tokamak coinciding with the second harmonic cyclotron resonance of D. The modelling takes into account the synergy between ICRF and NBI heating through the second harmonic cyclotron resonance of D beam ions, allowing us to assess its impact on the neutron rate R NT. For discharges carried out with a fixed ICRF antenna frequency and changing toroidal magnetic field to vary the resonance position, we evaluate the influence of the resonance position on the heating performance and central impurity control. The H concentration is varied between discharges in order to test its role in the heating performance. It is found that discharges with a resonance beyond ∼0.15 m from the magnetic axis R 0 suffer from MHD activity and impurity accumulation in these plasma conditions. According to our modelling, the ICRF enhancement of R NT increases with the ICRF power absorbed by deuterons as the H concentration decreases. We find that in the recent hybrid discharges, this ICRF enhancement varies due to a variation of H concentration and is in the range of 10%-25%. The modelling of a recent record high-performance hybrid discharge shows that ICRF fusion yield enhancement of ∼30% and ∼15% respectively can be achieved in the ramp-up phase and during the main heating phase. We extrapolate the results to DT and find that the best performing hybrid discharges correspond to an equivalent fusion power of ∼7.0 MW in DT. Finally, an optimization analysis of the bulk ion heating for the DT scenario reveals around 15%-20% larger bulk ion heating for the 3He minority scenario as compared to the H minority scenario.

AB - During the 2015-2016 JET campaigns, many efforts have been devoted to the exploration of high-performance plasma scenarios envisaged for DT operation in JET. In this paper, we review various key recent hybrid discharges and model the combined ICRF+NBI heating. These deuterium discharges with deuterium beams had the ICRF antenna frequency tuned to match the cyclotron frequency of minority H at the centre of the tokamak coinciding with the second harmonic cyclotron resonance of D. The modelling takes into account the synergy between ICRF and NBI heating through the second harmonic cyclotron resonance of D beam ions, allowing us to assess its impact on the neutron rate R NT. For discharges carried out with a fixed ICRF antenna frequency and changing toroidal magnetic field to vary the resonance position, we evaluate the influence of the resonance position on the heating performance and central impurity control. The H concentration is varied between discharges in order to test its role in the heating performance. It is found that discharges with a resonance beyond ∼0.15 m from the magnetic axis R 0 suffer from MHD activity and impurity accumulation in these plasma conditions. According to our modelling, the ICRF enhancement of R NT increases with the ICRF power absorbed by deuterons as the H concentration decreases. We find that in the recent hybrid discharges, this ICRF enhancement varies due to a variation of H concentration and is in the range of 10%-25%. The modelling of a recent record high-performance hybrid discharge shows that ICRF fusion yield enhancement of ∼30% and ∼15% respectively can be achieved in the ramp-up phase and during the main heating phase. We extrapolate the results to DT and find that the best performing hybrid discharges correspond to an equivalent fusion power of ∼7.0 MW in DT. Finally, an optimization analysis of the bulk ion heating for the DT scenario reveals around 15%-20% larger bulk ion heating for the 3He minority scenario as compared to the H minority scenario.

KW - ICRF heating

KW - JET hybrid plasmas

KW - NBI heating

KW - fusion enhancement

UR - https://www.scopus.com/pages/publications/85053375348

U2 - 10.1088/1741-4326/aad9ad

DO - 10.1088/1741-4326/aad9ad

M3 - Article

AN - SCOPUS:85053375348

SN - 0029-5515

VL - 58

JO - Nuclear Fusion

JF - Nuclear Fusion

IS - 10

M1 - 106037

ER -

Modelling of JET hybrid plasmas with emphasis on performance of combined ICRF and NBI heating

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