Progress of the JT-60SA project

J. Ongena; the JT-60SA Team and JT-60SA Research Plan Contributors

doi:10.1088/0029-5515/53/10/104010

Progress of the JT-60SA project

J. Ongena
, the JT-60SA Team and JT-60SA Research Plan Contributors

Laboratory for Plasma Physics

Japan Atomic Energy Agency
Fusion for Energy
JT-60SA Project Team
Commissariat à l'Énergie Atomique et aux Énergies Alternatives
National Institute for Fusion Science
CIEMAT
Max Planck Institute for Plasma Physics
Fusion for Energy
Association Euratom-ENEA
Consorzio Rfx
Centre National de la Recherche Scientifique
Culham Centre for Fusion Energy
Karlsruher Institut für Technologie
EFDA CSU-Garching
Istituto di Fisica del Plasma Piero Caldirola
STUDIECENTRUM VOOR KERNENERGIE / CENTRE D'ETUDE DE L'ENERGIE NUCLEAIRE
FOM Institute DIFFER
University of Tokyo
CNR
Osaka University
Kyoto University
Kyushu University
Keio University
CRIEPI
University of Tsukuba
Tokyo Institute of Technology
Nagoya University
Tohoku University
National Technical University of Athens
FORSCHUNGSZENTRUM JULICH GMBH
Kyoto Institute of Technology
Hokkaido University
EFDA-JET
Shizuoka University
Consorzio CREATE
Aalto University
Centre de recherches en physique des plasmas
University of York

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73 Citaten (Scopus)

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The JT-60SA project implemented by Japan and Europe is progressing on schedule towards the first plasma in March 2019. After careful R&D, procurements of the major components have entered their manufacturing stages. In parallel, disassembly of JT-60U has been completed on time, and the JT-60SA tokamak assembly is expected to start in January 2013. The JT-60SA device, a highly shaped large superconducting tokamak with a variety of plasma control actuators, has been designed in order to contribute to ITER and to complement ITER in all the major areas of fusion plasma development necessary to decide DEMO reactor construction. Detailed assessments and prediction studies of the JT-60SA plasma regimes have confirmed these capabilities: using ITER- and DEMO-relevant plasma regimes, heating conditions, and its sufficiently long discharge duration, JT-60SA enables studies on magnetohydrodynamic stability at high beta, heat/particle/momentum transport, high-energy ion physics, pedestal physics including edge localized mode control, and divertor physics. By integrating these studies, the project provides 'simultaneous and steady-state sustainment of the key performance characteristics required for DEMO' with integrated control scenario development.

Originele taal-2	Engels
Artikelnummer	104010
Tijdschrift	Nuclear Fusion
Volume	53
Nummer van het tijdschrift	10
DOI's	https://doi.org/10.1088/0029-5515/53/10/104010
Status	Gepubliceerd - okt. 2013

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@article{80082805d16c492ca9e323398b7a2a39,

title = "Progress of the JT-60SA project",

abstract = "The JT-60SA project implemented by Japan and Europe is progressing on schedule towards the first plasma in March 2019. After careful R\&D, procurements of the major components have entered their manufacturing stages. In parallel, disassembly of JT-60U has been completed on time, and the JT-60SA tokamak assembly is expected to start in January 2013. The JT-60SA device, a highly shaped large superconducting tokamak with a variety of plasma control actuators, has been designed in order to contribute to ITER and to complement ITER in all the major areas of fusion plasma development necessary to decide DEMO reactor construction. Detailed assessments and prediction studies of the JT-60SA plasma regimes have confirmed these capabilities: using ITER- and DEMO-relevant plasma regimes, heating conditions, and its sufficiently long discharge duration, JT-60SA enables studies on magnetohydrodynamic stability at high beta, heat/particle/momentum transport, high-energy ion physics, pedestal physics including edge localized mode control, and divertor physics. By integrating these studies, the project provides 'simultaneous and steady-state sustainment of the key performance characteristics required for DEMO' with integrated control scenario development.",

author = "Y. Kamada and P. Barabaschi and S. Ishida and \{Abdel Maksoud\}, W. and N. Aiba and N. Akino and T. Akiyama and J. Alonso and C. Angioni and T. Arai and H. Arakawa and F. Ardellier and J. Artaud and S. Asakawa and N. Asakura and N. Ashikawa and D. Balaguer and P. Barabaschi and E. Barbato and G. Barrera and M. Baruzzo and O. Baulaigue and P. Bayetti and M. B{\'e}coulet and S. Benkadda and F. Benoit and U. Besi and M. Beurskens and L. Boccaccini and T. Bolzonella and D. Borba and J. Botija and C. Bourdelle and G. Brolatti and A. Bruschi and J. Bucalossi and P. Cara and C. Challis and M. Chantant and I. Chapman and P. Chesny and S. Chiba and D. Ciayznski and F. Cismondi and V. Cocilovo and R. Coletti and A. Coletti and B. Collins and G. Conway and J. Ongena and \{the JT-60SA Team and JT-60SA Research Plan Contributors\}",

note = "Publisher Copyright: {\textcopyright} 2013 IAEA, Vienna.",

year = "2013",

month = oct,

doi = "10.1088/0029-5515/53/10/104010",

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AU - Ishida, S.

AU - Abdel Maksoud, W.

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AU - Akiyama, T.

AU - Alonso, J.

AU - Angioni, C.

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AU - Arakawa, H.

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AU - Benkadda, S.

AU - Benoit, F.

AU - Besi, U.

AU - Beurskens, M.

AU - Boccaccini, L.

AU - Bolzonella, T.

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AU - Coletti, R.

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AU - Ongena, J.

AU - the JT-60SA Team and JT-60SA Research Plan Contributors

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AB - The JT-60SA project implemented by Japan and Europe is progressing on schedule towards the first plasma in March 2019. After careful R&D, procurements of the major components have entered their manufacturing stages. In parallel, disassembly of JT-60U has been completed on time, and the JT-60SA tokamak assembly is expected to start in January 2013. The JT-60SA device, a highly shaped large superconducting tokamak with a variety of plasma control actuators, has been designed in order to contribute to ITER and to complement ITER in all the major areas of fusion plasma development necessary to decide DEMO reactor construction. Detailed assessments and prediction studies of the JT-60SA plasma regimes have confirmed these capabilities: using ITER- and DEMO-relevant plasma regimes, heating conditions, and its sufficiently long discharge duration, JT-60SA enables studies on magnetohydrodynamic stability at high beta, heat/particle/momentum transport, high-energy ion physics, pedestal physics including edge localized mode control, and divertor physics. By integrating these studies, the project provides 'simultaneous and steady-state sustainment of the key performance characteristics required for DEMO' with integrated control scenario development.

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Progress of the JT-60SA project

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