Your search keyword '"Marina Becoulet"' showing total 7 results

1. WEST Physics Basis

Author

Marc Missirlian, Pascale Hennequin, M. Yoshida, T. Loarer, A. Ekedahl, J. Decker, Patrick Maget, M. Firdaouss, Sylvain Brémond, Irena Ivanova-Stanik, E. Tsitrone, C. Grisolia, Lena Delpech, Marina Becoulet, C. Gil, X. Courtois, A. Kallenbach, Philippe Ghendrih, R. Zagórski, L. Colas, C. Fenzi, J.F. Artaud, T. Hoang, Roland Sabot, Guido Ciraolo, James Paul Gunn, Julien Hillairet, Frederic Imbeaux, P. Lotte, G. Giruzzi, P. Devynck, J. Garcia, P. Moreau, Patrick Mollard, Laure Vermare, M. Goniche, O. Meyer, Eric Nardon, Jérôme Bucalossi, B. Pégourié, R. J. Dumont, M. Schneider, P. Monier-Garbet, D. Douai, S. Vartanian, Yannick Marandet, Jochen Linke, Y. Peysson, Jet Contributors, J.-M. Travere, Clarisse Bourdelle, D. Guilhem, Hugo Bufferand, V. Basiuk, Yann Corre, R.P. Doerner, Guilhem Dif-Pradalier, F. Saint-Laurent, M.-L. Mayoral, Nicolas Fedorczak, A. Grosman, R. Guirlet, E. Joffrin, Universidad de Sevilla. Departamento de Física Atómica, Molecular y Nuclear, Laboratoire de Physique des Plasmas (LPP), Université Paris-Sud - Paris 11 (UP11)-Université Pierre et Marie Curie - Paris 6 (UPMC)-Observatoire de Paris, Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-École polytechnique (X)-Université Paris-Saclay-Centre National de la Recherche Scientifique (CNRS), Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-École polytechnique (X)-Sorbonne Université (SU)-Université Paris-Saclay-Centre National de la Recherche Scientifique (CNRS), IRFM-CEA, École Polytechnique Fedérale de Lausanne, VTT Technical Research Centre of Finland, Department of Applied Physics, Princeton University, Culham Science Centre, Uppsala University, European Commission, Chinese Academy of Sciences, National Fusion Research Institute, ITER, Universidad Politécnica de Madrid, School services,SCI, Sorbonne Université, Institute for Plasma Research, Universidade de Lisboa, Research Center Julich, University of Electronic Science and Technology of China, Aalto-yliopisto, Aalto University, and JET Contributors

Subjects

Nuclear and High Energy Physics, Long pulse, Tokamak, Nuclear engineering, TOKAMAKS, POWER, Tore Supra, PROFILE, 7. Clean energy, law.invention, Plasma physics, Pedestal, Divertor, law, [PHYS.PHYS.PHYS-PLASM-PH]Physics [physics]/Physics [physics]/Plasma Physics [physics.plasm-ph], divertor, User Facility, ddc:530, tokamak, LOSSES, Plasma facing components, Physics, TUNGSTEN, plasma physics, EXTRAPOLATION, Plasma, Condensed Matter Physics, plasma facing components, DENSITY PEAKING, TRANSPORT, Heat flux, BEHAVIOR

Abstract

International audience; With WEST (Tungsten Environment in Steady State Tokamak) (Bucalossi et al 2014 Fusion Eng. Des. 89 [http://dx.doi.org/10.1016/j.fusengdes.2014.01.062] 907?12 ), the Tore Supra facility and team expertise (Dumont et al 2014 Plasma Phys. Control. Fusion 56 [http://dx.doi.org/10.1088/0741-3335/56/7/075020] 075020 ) is used to pave the way towards ITER divertor procurement and operation. It consists in implementing a divertor configuration and installing ITER-like actively cooled tungsten monoblocks in the Tore Supra tokamak, taking full benefit of its unique long-pulse capability. WEST is a user facility platform, open to all ITER partners. This paper describes the physics basis of WEST: the estimated heat flux on the divertor target, the planned heating schemes, the expected behaviour of the L?H threshold and of the pedestal and the potential W sources. A series of operating scenarios has been modelled, showing that ITER-relevant heat fluxes on the divertor can be achieved in WEST long pulse H-mode plasmas.

Published

2015

2. Three-dimensional distortions of the tokamak plasma boundary: boundary displacements in the presence of resonant magnetic perturbations

Author

W. Suttrop, A. Kirk, C. J. Ham, Nathaniel Ferraro, Marina Becoulet, W. A. Cooper, Mikhail Gryaznevich, Nstx Team, Diii-D Team, R.A. Moyer, Efda-Jet Contributors, I. Lupelli, Y. Gribov, C. Nührenberg, James D. Hanson, Ch. Fuchs, Samuel Lazerson, Yunfeng Liang, D. Yadykin, D.M. Orlov, F. Orain, I. T. Chapman, T. Bird, Todd Evans, Mast Team, G. Huijsmans, John Canik, Mark Cianciosa, ASDEX Upgrade Team, Max Planck Institute for Plasma Physics, Max Planck Society, DIII-D Team, MAST Team, NSTX Team, and EFDA-JET Contributors

Subjects

Physics, Nuclear and High Energy Physics, Tokamak, Field line, Mechanics, Plasma, Condensed Matter Physics, Resonant magnetic perturbations, law.invention, Nonlinear system, Pedestal, ASDEX Upgrade, Physics::Plasma Physics, law, Magnetohydrodynamics, Atomic physics

Abstract

The three-dimensional plasma boundary displacements induced by applied non-axisymmetric magnetic perturbations have been measured in ASDEX Upgrade, DIII-D, JET, MAST and NSTX. The displacements arising from applied resonant magnetic perturbations (RMPs) are measured up to +/- 5% of the minor radius in present-day machines. Good agreement can be found between different experimental measurements and a range of models-be it vacuum field line tracing, ideal three-dimensional MHD equilibrium modelling, or nonlinear plasma amplification. The agreement of the various experimental measurements with the different predictions from these models is presented, and the regions of applicability of each discussed. The measured displacement of the outboard boundary from various machines is found to correlate approximately linearly with the applied resonant field predicted by vacuum modelling (though it should be emphasized that one should not infer that vacuum modelling accurately predicts the displacement inside the plasma). The RMP-induced displacements foreseen in ITER are expected to lie within the range of those predicted by the different models, meaning less than +/- 1.75% (+/- 3.5 cm) of the minor radius in the H-mode baseline and less than +/- 2.5% (+/- 5 cm) in a 9MA plasma. Whilst a displacement of 7 cm peak-to-peak in the baseline scenario is marginally acceptable from both a plasma control and heat loading perspective, it is important that ITER adopts a plasma control system which can account for a three-dimensional boundary corrugation to avoid an n = 0 correction which would otherwise locally exacerbate the displacement caused by the applied fields.

Published

2014

3. MHD stability of the pedestal in ITER scenarios

Author

J.F. Artaud, Marina Becoulet, J Faustin, J. Garcia, T.A. Casper, A. Loarte, Patrick Maget, Gta Guido Huijsmans, and G. Saibene

Subjects

Physics, Nuclear and High Energy Physics, Safety factor, Physics::Instrumentation and Detectors, Plasma, Mechanics, Condensed Matter Physics, Bootstrap current, Pedestal, Physics::Plasma Physics, Plasma shaping, Magnetohydrodynamic drive, Magnetohydrodynamics, Current density

Abstract

The linear ideal magnetohydrodynamic (MHD) limits of the pedestal in ITER scenarios associated with the preparation and realization of the nominal fusion gain Q?=?10 (inductive scenario at 15?MA/5.3?T, half-field/half-current and intermediate H-mode scenario at 10?MA/3.5?T), as well as the hybrid scenario at 12?MA/5.3?T, are investigated in this work. The accessible part of the MHD stability diagram is determined by computing the bootstrap current and self-consistently evaluating the corresponding pedestal current. This procedure shows that only a small part of peeling?ballooning diagrams is physically accessible. Uncertainties about the foreseen plasma profiles motivate studies evaluating the impact of various parameters on the pedestal limits. We have addressed issues such as the pedestal width, the global performance, pressure peaking, edge current density, internal inductance and plasma shaping. A scaling law for the maximum pedestal pressure in the ITER scenarios is proposed, highlighting that the main dependences are on the plasma current, the edge safety factor, the pedestal width and the internal inductance.

Published

2013

4. Resistive MHD simulation of edge-localized-modes for double-null discharges in the MAST device

Author

A. Kirk, James Harrison, G. T. A. Huijsmans, Marina Becoulet, Stanislas Pamela, R. Scannell, F. Orain, A.J. Thornton, and I. T. Chapman

Subjects

Physics, Resistive touchscreen, Divertor, Plasma, Condensed Matter Physics, Computational physics, Nonlinear system, Pedestal, Nuclear Energy and Engineering, Filamentation, Physics::Plasma Physics, Physics::Space Physics, Diamagnetism, Magnetohydrodynamics

Abstract

Recent development of the nonlinear magneto hydrodynamic (MHD) code JOREK has enabled the alignment of its two-dimensional finite-element grid along poloidal flux surfaces for double-null Grad–Shafranov equilibria. In previous works with the JOREK code, only single X-point plasmas were studied. The fast-camera diagnostic on MAST, which gives a global view of the pedestal filamentation during an ELM crash, clearly shows filaments travelling far into the scrape-off layer, as far as the first wall. Simulation of such a filament dynamics in MAST double-null plasmas is presented here and compared with experimental observations. In addition to direct comparison with the fast-camera images, general aspects of filaments are studied, such as their radial speed and composition. A qualitative validation of simulations is carried out against other diagnostics, such as the Thomson-scattering profiles or the infra-red camera images. Simulations are found to reproduce experimental edge localized modes in a reasonable manner, with similar energy losses and divertor heat-flux profiles. However, the MHD model used for those simulations is a reduced MHD model, which is likely approaching the limit of its applicability for the MAST device. Also, the absence of diamagnetic drift terms in the present MHD model results in nonlinear simulations being dominated by the highest mode number, and thus coupling with lower mode numbers is not observed.

Published

2013

5. ELM control strategies and tools: status and potential for ITER

Author

H. R. Wilson, Larry R. Baylor, Olaf Neubauer, Mario Cavinato, Minh Quang Tran, Peter Lang, Naoyuki Oyama, P.R. Thomas, M.J. Schaffer, A. Loarte, S. Clement-Lorenzo, C.G. Lowry, G. Saibene, Y. R. Martin, Marina Becoulet, L. D. Horton, A. Kavin, D. Stork, W. Suttrop, Y. Gribov, M.E. Fenstermacher, Oliver Schmitz, E. Daly, and Todd Evans

Subjects

Nuclear and High Energy Physics, Materials science, Pedestal, Nuclear engineering, Plasma shaping, fusion plasma tokamak ITER H-mode ELM control, Atmospheric-pressure plasma, Plasma, Magnetohydrodynamic drive, Edge (geometry), Condensed Matter Physics, Instability, Magnetic field

Abstract

Operating ITER in the reference inductive scenario at the design values of Ip = 15 MA and QDT = 10 requires the achievement of good H-mode confinement that relies on the presence of an edge transport barrier whose pedestal pressure height is key to plasma performance. Strong gradients occur at the edge in such conditions that can drive magnetohydrodynamic instabilities resulting in edge localized modes (ELMs), which produce a rapid energy loss from the pedestal region to the plasma facing components (PFC). Without appropriate control, the heat loads on PFCs during ELMs in ITER are expected to become significant for operation in H-mode at Ip = 6–9 MA; operation at higher plasma currents would result in a very reduced life time of the PFCs. Currently, several options are being considered for the achievement of the required level of ELM control in ITER; this includes operation in plasma regimes which naturally have no or very small ELMs, decreasing the ELM energy loss by increasing their frequency by a factor of up to 30 and avoidance of ELMs by actively controlling the edge with magnetic perturbations. Small/no ELM regimes obtained by influencing the edge stability (by plasma shaping, rotational shear control, etc) have shown in present experiments a significant reduction of the ELM heat fluxes compared to type-I ELMs. However, so far they have only been observed under a limited range of pedestal conditions depending on each specific device and their extrapolation to ITER remains uncertain. ELM control by increasing their frequency relies on the controlled triggering of the edge instability leading to the ELM. This has been presently demonstrated with the injection of pellets and with plasma vertical movements; pellets having provided the results more promising for application in ITER conditions. ELM avoidance/suppression takes advantage of the fact that relatively small changes in the pedestal plasma and magnetic field parameters seem to have a large stabilizing effect on large ELMs. Application of edge magnetic field perturbation with non-axisymmetric fields is found to affect transport at the plasma edge and thus prevent the uncontrolled rise of the plasma pressure gradients and the occurrence of type-I ELMs. This paper compiles a brief overview of various ELM control approaches, summarizes their present achievements and briefly discusses the open issues regarding their application in ITER.

Published

2013

6. Screening of resonant magnetic perturbations by flows in tokamaks

Author

E. G. Kaveeva, T.A. Casper, N. Mellet, M.J. Schaffer, Eric Nardon, A. Loarte, V. A. Rozhansky, Oliver Schmitz, M. Beurskens, Marina Becoulet, Todd Evans, Xavier Garbet, Patrick Maget, Yunfeng Liang, Andrei Smolyakov, F. Orain, G. T. A. Huysmans, P. Cahyna, and Francois Waelbroeck

Subjects

Physics, Nuclear and High Energy Physics, Tokamak, Plasma parameters, Screening effect, Plasma, Condensed Matter Physics, Resonant magnetic perturbations, law.invention, Magnetic field, Physics::Plasma Physics, law, Electric field, Diamagnetism, Atomic physics

Abstract

The non-linear reduced four-field RMHD model in cylindrical geometry was extended to include plasma rotation, neoclassical poloidal viscosity and two fluid diamagnetic effects. Interaction of the static resonant magnetic perturbations (RMPs) with the rotating plasmas in tokamaks was studied. The self-consistent evolution of equilibrium electric field due to RMP penetration is taken into account in the model. It is demonstrated that in the pedestal region with steep pressure gradients, mean flows perpendicular to the magnetic field, which includes and electron diamagnetic components plays an essential role in RMP screening by plasma. Generally, the screening effect increases for lower resistivity, stronger rotation and smaller RMP amplitude. Strong screening of central islands was observed limiting RMP penetration to the narrow region near the separatrix. However, at certain plasma parameters and due to the non-linear evolution of the radial electric field produced by RMPs, the rotation can be compensated by electron diamagnetic rotation locally. In this case, RMPs can penetrate and form magnetic islands. Typical plasma parameters and RMPs spectra on DIII-D, JET and ITER were used in modelling examples presented in the paper.

Published

2012

7. Physics of penetration of resonant magnetic perturbations used for Type I edge localized modes suppression in tokamaks

Author

Eric Nardon, Ker-Chung Shaing, Am Garofalo, D. F. Howell, P. Cahyna, Xavier Garbet, Jong-Kyu Park, G. T. A. Huysmans, M.J. Schaffer, Todd Evans, Marina Becoulet, and A. J. Cole

Subjects

Physics, Nuclear and High Energy Physics, Toroid, Tokamak, Plasma, Collisionality, Condensed Matter Physics, Resonant magnetic perturbations, law.invention, Physics::Plasma Physics, Electrical resistivity and conductivity, law, Harmonics, Atomic physics, Magnetohydrodynamics

Abstract

Non-linear reduced MHD modelling of the toroidally rotating plasma response to resonant magnetic perturbations (RMPs) is presented for DIII-D and ITER-like typical parameter and RMP coils. The non-linear cylindrical reduced MHD code was adapted to take into account toroidal rotation and plasma braking mechanisms such as resonant one (∼j × B) and the neoclassical toroidal viscosity (NTV) calculated for low collisionality regimes (‘1/ν’ and ‘ν’). Counter toroidal rotation by NTV is predicted for ITER with the proposed RMP coils in 1/ν-limit. Resonant braking is localized near resonant surfaces and is weak compared with NTV in the 1/ν regime for typical DIII-D and ITER parameters. Toroidal rotation leads to the effective screening of RMPs that is larger for stronger rotation and lower resistivity, resulting mainly in central islands screening. Non-resonant helical harmonics (q ≠ m/n) in RMP spectrum are not influenced by plasma rotation, and hence penetrate and are important in NTV mechanism.

Published

2009