Overview of JET results

JET-EFDA Contributors

doi:10.1088/0029-5515/49/10/104006

Overview of JET results

JET-EFDA Contributors

JET Joint Undertaking
IRFM, CEA
Helsinki University of Technology
UKAEA Fusion Association
RFX
Troitsk Insitute of Innovating and Thermonuclear Research (TRINITI)
Consorzio Rfx
Laboratorio Nacional de Fusion, CIEMAT
Instituto Superior Técnico
Wigner Research Centre for Physics
Chalmers University of Technology
Uppsala University
National Research Centre "Kurchatov Institute"
National Institute for Laser, Plasma and Radiation Physics
Association Euratom-MEdC
Max Planck Institute for Plasma Physics
Dublin City University
Fusion for Energy
EPFL
Culham Science Centre
Nuclear Fuel Plant
Queen's University Belfast
Lehigh University
Oak Ridge National Laboratory
Kernforschungszentrum Karlsruhe
Center for Autonomous Systems
University of Texas at Austin
Association Euratom-IPPLM
Université de Nice-Sophia Antipolis
LPP-ERM/KMS
EFDA-Close Support Unit
Forschungszentrum Jülich (FZJ)
The National Institute for Optoelectronics
Princeton Plasma Physics Laboratory
Colorado School of Mines
Japan Atomic Energy Agency
The Russian Academy of Sciences
Ghent University
CEA LIST Interactive Robotics Laboratory
EURATOM Association
Institute of Plasma Physics of the Czech Academy of Sciences
NCSR Demokritos
Poliehnica University
General Atomics
Istituto di Fisica del Plasma Piero Caldirola
Imperial College London
Center for Molecular Medicine of the Austrian Academy of Sciences
University of Maryland, College Park
Association Euratom-TEKES
Lund University
Graz University of Technology (TU Graz)
Massachusetts Institute of Technology
Jožef Stefan Institute
Technical University of Denmark
Université Libre de Bruxelles
University of Strathclyde
Politecnico di Torino
CEA Saclay
INRNE BAS Sofia
University of York
Institute of Plasma Physics Chinese Academy of Sciences

Research output: Contribution to journal › Article › peer-review

47 Scopus citations

Abstract

Since the last IAEA conference, the scientific programme of JET has focused on the qualification of the integrated operating scenarios for ITER and on physics issues essential for the consolidation of design choices and the efficient exploitation of ITER. Particular attention has been given to the characterization of the edge plasma, pedestal energy and edge localized modes (ELMs), and their impact on plasma facing components (PFCs). Various ELM mitigation techniques have been assessed for all ITER operating scenarios using active methods such as resonant magnetic field perturbation, rapid variation of the radial field and pellet pacing. In particular, the amplitude and frequency of type I ELMs have been actively controlled over a wide parameter range (q₉₅ = 3-4.8, β_N ≥ 3.0) by adjusting the amplitude of the n = 1 external perturbation field induced by error field correction coils. The study of disruption induced heat loads on PFCs has taken advantage of a new wide-angle viewing infrared system and a fast bolometer to provide a detailed account of time, localization and form of the energy deposition. Specific ITER-relevant studies have used the unique JET capability of varying the toroidal field (TF) ripple from its normal low value δ_BT = 0.08% up to δ_BT = 1% to study the effect of TF ripple on high confinement-mode plasmas. The results suggest that δ_BT < 0.5% is required on ITER to maintain adequate confinement to allow QDT = 10 at full field. Physics issues of direct relevance to ITER include heat and toroidal momentum transport, with experiments using power modulation to decouple power input and torque to achieve first experimental evidence of inward momentum pinch in JET and determine the threshold for ion temperature gradient driven modes. Within the longer term JET programme in support of ITER, activities aiming at the modification of the JET first wall and divertor and the upgrade of the neutral beam and plasma control systems are being conducted. The procurement of all components will be completed by 2009 with the shutdown for the installation of the beryllium wall and tungsten divertor extending from summer 2009 to summer 2010.

Original language	English
Article number	104006
Journal	Nuclear Fusion
Volume	49
Issue number	10
DOIs	https://doi.org/10.1088/0029-5515/49/10/104006
State	Published - 2009
Externally published	Yes

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@article{081d91ff9d034c398f3cb52cabb612ee,

title = "Overview of JET results",

abstract = "Since the last IAEA conference, the scientific programme of JET has focused on the qualification of the integrated operating scenarios for ITER and on physics issues essential for the consolidation of design choices and the efficient exploitation of ITER. Particular attention has been given to the characterization of the edge plasma, pedestal energy and edge localized modes (ELMs), and their impact on plasma facing components (PFCs). Various ELM mitigation techniques have been assessed for all ITER operating scenarios using active methods such as resonant magnetic field perturbation, rapid variation of the radial field and pellet pacing. In particular, the amplitude and frequency of type I ELMs have been actively controlled over a wide parameter range (q95 = 3-4.8, βN ≥ 3.0) by adjusting the amplitude of the n = 1 external perturbation field induced by error field correction coils. The study of disruption induced heat loads on PFCs has taken advantage of a new wide-angle viewing infrared system and a fast bolometer to provide a detailed account of time, localization and form of the energy deposition. Specific ITER-relevant studies have used the unique JET capability of varying the toroidal field (TF) ripple from its normal low value δBT = 0.08\% up to δBT = 1\% to study the effect of TF ripple on high confinement-mode plasmas. The results suggest that δBT < 0.5\% is required on ITER to maintain adequate confinement to allow QDT = 10 at full field. Physics issues of direct relevance to ITER include heat and toroidal momentum transport, with experiments using power modulation to decouple power input and torque to achieve first experimental evidence of inward momentum pinch in JET and determine the threshold for ion temperature gradient driven modes. Within the longer term JET programme in support of ITER, activities aiming at the modification of the JET first wall and divertor and the upgrade of the neutral beam and plasma control systems are being conducted. The procurement of all components will be completed by 2009 with the shutdown for the installation of the beryllium wall and tungsten divertor extending from summer 2009 to summer 2010.",

author = "\{JET-EFDA Contributors\} and F. Romanelli and R. Kamendjea and G. Agarici and M. Airila and R. Akers and Th Alarcon and R. Albanese and A. Alexeev and A. Alfier and P. Allan and S. Almaviva and A. Alonso and M. Alonso and B. Alper and H. Altmann and D. Alves and G. Ambrosino and V. Amosov and G. Anda and F. Andersson and E. Andersson-Sund{\'e}n and V. Andreev and Andrew, \{P. L.\} and Y. Andrew and M. Angelone and A. Anghel and M. Anghel and C. Angioni and G. Apruzzese and N. Arcis and A. Argouach and M. Ariola and A. Armitano and R. Armstrong and G. Arnoux and S. Arshad and G. Artaserse and Artaud, \{J. F.\} and A. Ash and E. Asp and O. Asunta and Atanasiu, \{C. V.\} and G. Atkins and Axton, \{M. D.\} and A. Baciero and V. Bailescu and Baker, \{R. A.\} and I. Balbao and N. Balshaw and R. Neu",

note = "Publisher Copyright: {\textcopyright} 2009 IAEA, Vienna.",

year = "2009",

doi = "10.1088/0029-5515/49/10/104006",

language = "English",

volume = "49",

journal = "Nuclear Fusion",

issn = "0029-5515",

publisher = "IOP Publishing Ltd.",

number = "10",

}

TY - JOUR

T1 - Overview of JET results

AU - JET-EFDA Contributors

AU - Romanelli, F.

AU - Kamendjea, R.

AU - Agarici, G.

AU - Airila, M.

AU - Akers, R.

AU - Alarcon, Th

AU - Albanese, R.

AU - Alexeev, A.

AU - Alfier, A.

AU - Allan, P.

AU - Almaviva, S.

AU - Alonso, A.

AU - Alonso, M.

AU - Alper, B.

AU - Altmann, H.

AU - Alves, D.

AU - Ambrosino, G.

AU - Amosov, V.

AU - Anda, G.

AU - Andersson, F.

AU - Andersson-Sundén, E.

AU - Andreev, V.

AU - Andrew, P. L.

AU - Andrew, Y.

AU - Angelone, M.

AU - Anghel, A.

AU - Anghel, M.

AU - Angioni, C.

AU - Apruzzese, G.

AU - Arcis, N.

AU - Argouach, A.

AU - Ariola, M.

AU - Armitano, A.

AU - Armstrong, R.

AU - Arnoux, G.

AU - Arshad, S.

AU - Artaserse, G.

AU - Artaud, J. F.

AU - Ash, A.

AU - Asp, E.

AU - Asunta, O.

AU - Atanasiu, C. V.

AU - Atkins, G.

AU - Axton, M. D.

AU - Baciero, A.

AU - Bailescu, V.

AU - Baker, R. A.

AU - Balbao, I.

AU - Balshaw, N.

AU - Neu, R.

PY - 2009

Y1 - 2009

N2 - Since the last IAEA conference, the scientific programme of JET has focused on the qualification of the integrated operating scenarios for ITER and on physics issues essential for the consolidation of design choices and the efficient exploitation of ITER. Particular attention has been given to the characterization of the edge plasma, pedestal energy and edge localized modes (ELMs), and their impact on plasma facing components (PFCs). Various ELM mitigation techniques have been assessed for all ITER operating scenarios using active methods such as resonant magnetic field perturbation, rapid variation of the radial field and pellet pacing. In particular, the amplitude and frequency of type I ELMs have been actively controlled over a wide parameter range (q95 = 3-4.8, βN ≥ 3.0) by adjusting the amplitude of the n = 1 external perturbation field induced by error field correction coils. The study of disruption induced heat loads on PFCs has taken advantage of a new wide-angle viewing infrared system and a fast bolometer to provide a detailed account of time, localization and form of the energy deposition. Specific ITER-relevant studies have used the unique JET capability of varying the toroidal field (TF) ripple from its normal low value δBT = 0.08% up to δBT = 1% to study the effect of TF ripple on high confinement-mode plasmas. The results suggest that δBT < 0.5% is required on ITER to maintain adequate confinement to allow QDT = 10 at full field. Physics issues of direct relevance to ITER include heat and toroidal momentum transport, with experiments using power modulation to decouple power input and torque to achieve first experimental evidence of inward momentum pinch in JET and determine the threshold for ion temperature gradient driven modes. Within the longer term JET programme in support of ITER, activities aiming at the modification of the JET first wall and divertor and the upgrade of the neutral beam and plasma control systems are being conducted. The procurement of all components will be completed by 2009 with the shutdown for the installation of the beryllium wall and tungsten divertor extending from summer 2009 to summer 2010.

AB - Since the last IAEA conference, the scientific programme of JET has focused on the qualification of the integrated operating scenarios for ITER and on physics issues essential for the consolidation of design choices and the efficient exploitation of ITER. Particular attention has been given to the characterization of the edge plasma, pedestal energy and edge localized modes (ELMs), and their impact on plasma facing components (PFCs). Various ELM mitigation techniques have been assessed for all ITER operating scenarios using active methods such as resonant magnetic field perturbation, rapid variation of the radial field and pellet pacing. In particular, the amplitude and frequency of type I ELMs have been actively controlled over a wide parameter range (q95 = 3-4.8, βN ≥ 3.0) by adjusting the amplitude of the n = 1 external perturbation field induced by error field correction coils. The study of disruption induced heat loads on PFCs has taken advantage of a new wide-angle viewing infrared system and a fast bolometer to provide a detailed account of time, localization and form of the energy deposition. Specific ITER-relevant studies have used the unique JET capability of varying the toroidal field (TF) ripple from its normal low value δBT = 0.08% up to δBT = 1% to study the effect of TF ripple on high confinement-mode plasmas. The results suggest that δBT < 0.5% is required on ITER to maintain adequate confinement to allow QDT = 10 at full field. Physics issues of direct relevance to ITER include heat and toroidal momentum transport, with experiments using power modulation to decouple power input and torque to achieve first experimental evidence of inward momentum pinch in JET and determine the threshold for ion temperature gradient driven modes. Within the longer term JET programme in support of ITER, activities aiming at the modification of the JET first wall and divertor and the upgrade of the neutral beam and plasma control systems are being conducted. The procurement of all components will be completed by 2009 with the shutdown for the installation of the beryllium wall and tungsten divertor extending from summer 2009 to summer 2010.

UR - https://www.scopus.com/pages/publications/67649460157

U2 - 10.1088/0029-5515/49/10/104006

DO - 10.1088/0029-5515/49/10/104006

M3 - Article

AN - SCOPUS:67649460157

SN - 0029-5515

VL - 49

JO - Nuclear Fusion

JF - Nuclear Fusion

IS - 10

M1 - 104006

ER -

Overview of JET results

Abstract

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