Magnetic configuration effects on the Wendelstein 7-X stellarator

the W7-X Team

doi:10.1038/s41567-018-0141-9

Magnetic configuration effects on the Wendelstein 7-X stellarator

the W7-X Team

Max-Planck-Institut für Plasmaphysik
Greifswald University
Technical University of Berlin
FORSCHUNGSZENTRUM JULICH GMBH
CIEMAT
The Australian National University
University of Wisconsin-Madison
Wigner Research Centre for Physics
Princeton Plasma Physics Laboratory
Los Alamos National Laboratory
University of Maryland, College Park
Lithuanian Energy Institute
Massachusetts Institute of Technology
Narodowe Centrum Badań Jadrowych
KARLSRUHER INSTITUT FUER TECHNOLOGIE
Eindhoven University of Technology
University of Cagliari
Consorzio Rfx
Instituto Superior Técnico
Ioffe Physical-Technical Institute of the Russian Academy of Sciences
Oak Ridge National Laboratory
University of Salerno
Warsaw University of Technology
ENEA Centro Ricerche Frascati
Institute of Nuclear Physics PAN
University of Szczecin
University of Milano-Bicocca
Auburn University
Brandenburg University of Technology Cottbus-Senftenberg
National Institute for Fusion Science
Universidad Carlos III de Madrid
Commissariat à l'Énergie Atomique (CEA)
Culham Centre for Fusion Energy
Budker Institute of Nuclear Physics (BINP)
University of Stuttgart
Fraunhofer-Institut für Schicht- und Oberflächentechnik IST
Austrian Academy of Science
Institute for Nuclear Research
Russian Academy of Science
University of Opole
Aalto University
Physikalisch Technische Bundesanstalt (PTB)
Kyoto University
Institute of Plasma Physics Chinese Academy of Sciences
Institute of Plasma Physics, Academy of Sciences of the Czech Republic
Instituto di Fisica del Plasma ‘Piero Caldirola’
Fraunhofer-Institut für Werkzeugmaschinen und Umformtechnik IWU
Universität in Rostock
Lawrence University, Appleton
CNR
Universitat Innsbruck

Publikation: Beitrag in Fachzeitschrift › Artikel › Begutachtung

151 Zitate (Scopus)

Abstract

The two leading concepts for confining high-temperature fusion plasmas are the tokamak and the stellarator. Tokamaks are rotationally symmetric and use a large plasma current to achieve confinement, whereas stellarators are non-axisymmetric and employ three-dimensionally shaped magnetic field coils to twist the field and confine the plasma. As a result, the magnetic field of a stellarator needs to be carefully designed to minimize the collisional transport arising from poorly confined particle orbits, which would otherwise cause excessive power losses at high plasma temperatures. In addition, this type of transport leads to the appearance of a net toroidal plasma current, the so-called bootstrap current. Here, we analyse results from the first experimental campaign of the Wendelstein 7-X stellarator, showing that its magnetic-field design allows good control of bootstrap currents and collisional transport. The energy confinement time is among the best ever achieved in stellarators, both in absolute figures (τ_E > 100 ms) and relative to the stellarator confinement scaling. The bootstrap current responds as predicted to changes in the magnetic mirror ratio. These initial experiments confirm several theoretically predicted properties of Wendelstein 7-X plasmas, and already indicate consistency with optimization measures.

Originalsprache	Englisch
Seiten (von - bis)	855-860
Seitenumfang	6
Fachzeitschrift	Nature Physics
Jahrgang	14
Ausgabenummer	8
DOIs	https://doi.org/10.1038/s41567-018-0141-9
Publikationsstatus	Veröffentlicht - 1 Aug. 2018

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@article{7b8657d2cd9d47d3afd8fa27b363d107,

title = "Magnetic configuration effects on the Wendelstein 7-X stellarator",

abstract = "The two leading concepts for confining high-temperature fusion plasmas are the tokamak and the stellarator. Tokamaks are rotationally symmetric and use a large plasma current to achieve confinement, whereas stellarators are non-axisymmetric and employ three-dimensionally shaped magnetic field coils to twist the field and confine the plasma. As a result, the magnetic field of a stellarator needs to be carefully designed to minimize the collisional transport arising from poorly confined particle orbits, which would otherwise cause excessive power losses at high plasma temperatures. In addition, this type of transport leads to the appearance of a net toroidal plasma current, the so-called bootstrap current. Here, we analyse results from the first experimental campaign of the Wendelstein 7-X stellarator, showing that its magnetic-field design allows good control of bootstrap currents and collisional transport. The energy confinement time is among the best ever achieved in stellarators, both in absolute figures (τE > 100 ms) and relative to the stellarator confinement scaling. The bootstrap current responds as predicted to changes in the magnetic mirror ratio. These initial experiments confirm several theoretically predicted properties of Wendelstein 7-X plasmas, and already indicate consistency with optimization measures.",

author = "A. Dinklage and Beidler, \{C. D.\} and P. Helander and G. Fuchert and H. Maa{\ss}berg and K. Rahbarnia and \{Sunn Pedersen\}, T. and Y. Turkin and Wolf, \{R. C.\} and T. Andreeva and S. Bozhenkov and B. Buttensch{\"o}n and Y. Feng and J. Geiger and M. Hirsch and U. H{\"o}fel and M. Jakubowski and T. Klinger and J. Knauer and A. Langenberg and Laqua, \{H. P.\} and N. Marushchenko and A. Moll{\'e}n and U. Neuner and H. Niemann and E. Pasch and L. Rudischhauser and Smith, \{H. M.\} and T. Stange and G. Weir and T. Windisch and D. Zhang and S. {\"A}k{\"a}slompolo and A. Ali and \{Alcuson Belloso\}, J. and P. Aleynikov and K. Aleynikova and J. Baldzuhn and M. Banduch and C. Beidler and A. Benndorf and M. Beurskens and C. Biedermann and M. Vervier and F. Durodie and A. Goriaev and Y. Kazakov and J. Ongena and M. Vergote and T. Wauters and \{the W7-X Team\}",

note = "Publisher Copyright: {\textcopyright} 2018, The Author(s).",

year = "2018",

month = aug,

day = "1",

doi = "10.1038/s41567-018-0141-9",

language = "English",

volume = "14",

pages = "855--860",

journal = "Nature Physics",

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TY - JOUR

T1 - Magnetic configuration effects on the Wendelstein 7-X stellarator

AU - Dinklage, A.

AU - Beidler, C. D.

AU - Helander, P.

AU - Fuchert, G.

AU - Maaßberg, H.

AU - Rahbarnia, K.

AU - Sunn Pedersen, T.

AU - Turkin, Y.

AU - Wolf, R. C.

AU - Andreeva, T.

AU - Bozhenkov, S.

AU - Buttenschön, B.

AU - Feng, Y.

AU - Geiger, J.

AU - Hirsch, M.

AU - Höfel, U.

AU - Jakubowski, M.

AU - Klinger, T.

AU - Knauer, J.

AU - Langenberg, A.

AU - Laqua, H. P.

AU - Marushchenko, N.

AU - Mollén, A.

AU - Neuner, U.

AU - Niemann, H.

AU - Pasch, E.

AU - Rudischhauser, L.

AU - Smith, H. M.

AU - Stange, T.

AU - Weir, G.

AU - Windisch, T.

AU - Zhang, D.

AU - Äkäslompolo, S.

AU - Ali, A.

AU - Alcuson Belloso, J.

AU - Aleynikov, P.

AU - Aleynikova, K.

AU - Baldzuhn, J.

AU - Banduch, M.

AU - Beidler, C.

AU - Benndorf, A.

AU - Beurskens, M.

AU - Biedermann, C.

AU - Vervier, M.

AU - Durodie, F.

AU - Goriaev, A.

AU - Kazakov, Y.

AU - Ongena, J.

AU - Vergote, M.

AU - Wauters, T.

AU - the W7-X Team

PY - 2018/8/1

Y1 - 2018/8/1

N2 - The two leading concepts for confining high-temperature fusion plasmas are the tokamak and the stellarator. Tokamaks are rotationally symmetric and use a large plasma current to achieve confinement, whereas stellarators are non-axisymmetric and employ three-dimensionally shaped magnetic field coils to twist the field and confine the plasma. As a result, the magnetic field of a stellarator needs to be carefully designed to minimize the collisional transport arising from poorly confined particle orbits, which would otherwise cause excessive power losses at high plasma temperatures. In addition, this type of transport leads to the appearance of a net toroidal plasma current, the so-called bootstrap current. Here, we analyse results from the first experimental campaign of the Wendelstein 7-X stellarator, showing that its magnetic-field design allows good control of bootstrap currents and collisional transport. The energy confinement time is among the best ever achieved in stellarators, both in absolute figures (τE > 100 ms) and relative to the stellarator confinement scaling. The bootstrap current responds as predicted to changes in the magnetic mirror ratio. These initial experiments confirm several theoretically predicted properties of Wendelstein 7-X plasmas, and already indicate consistency with optimization measures.

AB - The two leading concepts for confining high-temperature fusion plasmas are the tokamak and the stellarator. Tokamaks are rotationally symmetric and use a large plasma current to achieve confinement, whereas stellarators are non-axisymmetric and employ three-dimensionally shaped magnetic field coils to twist the field and confine the plasma. As a result, the magnetic field of a stellarator needs to be carefully designed to minimize the collisional transport arising from poorly confined particle orbits, which would otherwise cause excessive power losses at high plasma temperatures. In addition, this type of transport leads to the appearance of a net toroidal plasma current, the so-called bootstrap current. Here, we analyse results from the first experimental campaign of the Wendelstein 7-X stellarator, showing that its magnetic-field design allows good control of bootstrap currents and collisional transport. The energy confinement time is among the best ever achieved in stellarators, both in absolute figures (τE > 100 ms) and relative to the stellarator confinement scaling. The bootstrap current responds as predicted to changes in the magnetic mirror ratio. These initial experiments confirm several theoretically predicted properties of Wendelstein 7-X plasmas, and already indicate consistency with optimization measures.

UR - https://www.scopus.com/pages/publications/85047206432

U2 - 10.1038/s41567-018-0141-9

DO - 10.1038/s41567-018-0141-9

M3 - Article

AN - SCOPUS:85047206432

SN - 1745-2473

VL - 14

SP - 855

EP - 860

JO - Nature Physics

JF - Nature Physics

IS - 8

ER -

Magnetic configuration effects on the Wendelstein 7-X stellarator

Abstract

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