Your search keyword '"Mehdi Firdaouss"' showing total 3 results

1. Heat flux analysis of Type I ELM impact on a sloped, protruding surface in the JET bulk tungsten divertor

Author

Alexander Lukin, Jan Willem Coenen, Stefan Matejcik, Soare Sorin, Francesco Romanelli, Karl Krieger, Bohdan Bieg, Mehdi Firdaouss, Jonathan GASPAR, Vladislav Plyusnin, José Vicente, Alberto Loarte, Bor Kos, Axel Jardin, Rajnikant Makwana, CHIARA MARCHETTO, William Tang, Choong-Seock Chang, Manuel Garcia-munoz, Institut universitaire des systèmes thermiques industriels (IUSTI), Aix Marseille Université (AMU)-Centre National de la Recherche Scientifique (CNRS), Institut de Recherche sur la Fusion par confinement Magnétique (IRFM), Commissariat à l'énergie atomique et aux énergies alternatives (CEA), Institute of Plasma Physics, Association Euratom/IPP.CR (IPP PRAGUE), Czech Academy of Sciences [Prague] (CAS), Association EURATOM-CEA (CEA/DSM/DRFC), Culham Centre for Fusion Energy (CCFE), EURATOM/CCFE Fusion Association, Culham Science Centre [Abingdon], Universidad de Sevilla. Departamento de Física Atómica, Molecular y Nuclear, Universidad de Sevilla. RNM138: Física Nuclear Aplicada, JET Contributors, Department of Physics, and Materials Physics

Subjects

Surface (mathematics), IR data, Nuclear and High Energy Physics, Materials science, Materials Science (miscellaneous), education, chemistry.chemical_element, Spatial resolution effect, Tungsten, Edge (geometry), 01 natural sciences, 114 Physical sciences, 010305 fluids & plasmas, Optical projection, Fusion, plasma och rymdfysik, Physics::Plasma Physics, PIC modelling, [PHYS.PHYS.PHYS-PLASM-PH]Physics [physics]/Physics [physics]/Plasma Physics [physics.plasm-ph], 0103 physical sciences, 010306 general physics, Jet (fluid), Fusion, Divertor, Mechanics, ELM heat flux analysis, Fusion, Plasma and Space Physics, lcsh:TK9001-9401, Nuclear Energy and Engineering, chemistry, Heat flux, Ion orbit modelling, [PHYS.MECA.THER]Physics [physics]/Mechanics [physics]/Thermics [physics.class-ph], lcsh:Nuclear engineering. Atomic power, Transient (oscillation)

Abstract

Tungsten (W) melting due to transient power loads, for example those delivered by edge localised modes (ELMs), is a major concern for next step fusion devices. A series of experiments has been performed on JET to investigate the dynamics of Type-I ELM-induced transient melting. Following initial exposures in 2013 of a W-lamella with sharp leading edge in the bulk W outer divertor, new experiments have been performed in 2016–2017 on a protruding W-lamella with a 15° slope, allowing direct and spatially resolved (0.85 mm/pixel) observation of the top surface using the IR thermography system viewing from the top of the poloidal cross-section. Thermal and IR analysis have already been conducted assuming the geometrical projection of the parallel heat flux on the W-lamellas, thus ignoring the gyro-radius orbit of plasma particles. Although it is well justified during L-mode or inter-ELM period, the hypothesis becomes questionable during ELM when the ion Larmor radius is larger. The goal of this paper is to extend the previous analysis based on the forward approach to the H-mode discharges and investigate in particular the gyro-radius effect during the Type-I ELMs, those used to achieve transient melting on the slope of the protruding W-lamella. Surface temperatures measured by the IR camera are compared with reconstructed synthetic data from 3D thermal modelling using heat loads derived from optical projection of the parallel heat flux (ignoring the gyro-radius orbit), 2D gyro-radius orbit and particle-in-cell (PIC) simulations describing the influence of finite Larmor-radius effects and electrical potential on the deposited power flux. Results show that the ELM power deposition behaves differently than the optical projection of the parallel heat flux, contrary to the L-mode observations, and may thus be due to the much larger gyro-orbits of the energetic ELM ions in comparison to L-mode or inter-ELM conditions. Keywords: ELM heat flux analysis, Optical projection, PIC modelling, Ion orbit modelling, IR data, Spatial resolution effect

Published

2018

2. RF Sheath-Enhanced Plasma Surface Interaction Studies using Beryllium Optical Emission Spectroscopy in JET ITER-Like Wall

Author

Carine Giroud, Pierre Dumortier, Mehdi Firdaouss, Krassimir Kirov, C. Christopher Klepper, F. Durodié, Laurent Colas, Ane Lasa, V. Bobkov, E. Delabie, Alena Křivská, Philippe Jacquet, Ernesto Lerche, and JET Contributors

Subjects

Physics, Jet (fluid), business.industry, QC1-999, Electrical engineering, chemistry.chemical_element, 01 natural sciences, Phaser, 010305 fluids & plasmas, Magnetic field, Optics, chemistry, Electric field, 0103 physical sciences, Limiter, Pitch angle, Antenna (radio), Beryllium, 010306 general physics, business

Abstract

A dedicated study on JET-ILW, deploying two types of ICRH antennas and spectroscopic observation spots at two outboard, beryllium limiters, has provided insight on long-range (up to 6m) RFenhanced plasma-surface interactions (RF-PSI) due to near-antenna electric fields. To aid in the interpretation of optical emission measurements of these effects, the antenna near-fields are computed using the TOPICA code, specifically run for the ITER-like antenna (ILA); similar modelling already existed for the standard JET antennas (A2). In the experiment, both antennas were operated in current drive mode, as RF-PSI tends to be higher in this phasing and at similar power (∼0.5 MW). When sweeping the edge magnetic field pitch angle, peaked RF-PSI effects, in the form of 2-4 fold increase in the local Be source,are consistently measured with the observation spots magnetically connect to regions of TOPICAL-calculated high near-fields, particularly at the near-antenna limiters. It is also found that similar RF-PSI effects are produced by the two types of antenna on similarly distant limiters. Although this mapping of calculated near-fields to enhanced RF-PSI gives only qualitative interpretion of the data, the present dataset is expected to provide a sound experimental basis for emerging RF sheath simulation model validation.

Published

2017

3. First ERO2.0 modeling of Be erosion and non-local transport in JET ITER-like wall

Author

Dmitriy V. Borodin, Alexander Lukin, Stefan Matejcik, Soare Sorin, Francesco Romanelli, Paul Gibbon, Valentina Huber, Sebastijan Brezinsek, Bohdan Bieg, Mehdi Firdaouss, Alexander Huber, Vladislav Plyusnin, José Vicente, Alberto Loarte, Alina Eksaeva, Axel Jardin, Andreas Kirschner, Rajnikant Makwana, CHIARA MARCHETTO, Marco Wischmeier, William Tang, Choong-Seock Chang, Manuel Garcia-munoz, Universidad de Sevilla. Departamento de Física Atómica, Molecular y Nuclear, and Universidad de Sevilla. RNM138: Física Nuclear Aplicada

Subjects

Fusion, Jet (fluid), Materials science, JET ITER-like wall, Nuclear engineering, Astrophysics::Cosmology and Extragalactic Astrophysics, Plasma, Condensed Matter Physics, Non local, 01 natural sciences, Atomic and Molecular Physics, and Optics, 010305 fluids & plasmas, Beryllium, Upgrade, Erosion, Physics::Plasma Physics, Physics::Space Physics, 0103 physical sciences, ddc:530, 010306 general physics, ERO, Mathematical Physics

Abstract

ERO is a Monte-Carlo code for modeling plasma-wall interaction and 3D plasma impurity transport for applications in fusion research. The code has undergone a significant upgrade (ERO2.0) which allows increasing the simulation volume in order to cover the entire plasma edge of a fusion device, allowing a more self-consistent treatment of impurity transport and comparison with a larger number and variety of experimental diagnostics. In this contribution, the physics-relevant technical innovations of the new code version are described and discussed. The new capabilities of the code are demonstrated by modeling of beryllium (Be) erosion of the main wall during JET limiter discharges. Results for erosion patterns along the limiter surfaces and global Be transport including incident particle distributions are presented. A novel synthetic diagnostic, which mimics experimental wide-angle 2D camera images, is presented and used for validating various aspects of the code, including erosion, magnetic shadowing, non-local impurity transport, and light emission simulation. EURATOM 633053

Published

2017