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tel +32-2-650.59.18, fax +32-2-650.58.24,
Campus de la Plaine
CP231, boulevard du Triomphe, 1050 Bruxelles

unités de recherche

Dynamique des fluides et des plasmas [Fluid and plasma dynamics] (Aqua)


Physique des plasmas de fusion [Fusion plasma physics]
Théorie cinétique et modélisation des processus de transport dans les plasmas. Etude théorique et numérique de la turbulence dans les plasmas confinés magnétiquement. Influence du chauffage par injection d'ondes électromagnétiques sur les plasmas dans les tokamaks. Caractérisation des trajectoires de particules chargées dans des champs électromagnétiques complexes. Simulation gyrocinétiques. [Kinetic theory and modelling of transport processes. Theoretical and numerical study of turbulence in magnetically confined plasmas. Influence of radio-frequency heating on tokamaks plasmas. Characterisation of charged particle trajectories in complex electromagnetic fields. Gyrokinetic simulations.]

Modélisation et simulation d'écoulements turbulents conducteurs dans la limite des faibles nombres de Reynolds magnétiques. [Modelling and simulation of turbulent conductive flows in the limit of a low magnetic Reynolds number.]
Modélisation et simulation d'écoulements turbulents conducteurs dans la limite des faibles nombres de Reynolds magnétiques. [Most fluid flows encountered in real life fall into the category of turbulent flows. As such, they are characterised by very complex motions that can be qualified as chaotic and random. The prediction of the evolution of turbulent flows is a complex but important task as such flows are essential ingredients in many physical systems and industrial applications. In this research, the focus is placed on the study of turbulent conductive flows in the limit of a vanishing magnetic Reynolds number. In this limit, the motion of the conductive flow can be significantly influenced by an electromagnetic field but cannot appreciably retroact on it. For instance, magnetic fields are used to control flow evolution in the steel industry and the crystallisation of semiconductor crystals. Interaction of liquid metals with magnetic fields is also an essential question in the design of coolant blankets for nuclear fusion reactors. Although widely used in technological applications, the interaction of conductive flows with applied electromagnetic fields in turbulent situations still cannot be predicted in a satisfactory manner. We will study this interaction further. Since no exact mathematical framework is available to solve turbulent flow problems, there is currently a great need for efficient numerical tools to predict them. In order to analyze and predict the kinds of flows encountered in real-world applications, a versatile simulation code will be developed. Different approximate methods will be incorporated in this code, among them the method of large-eddy simulations in which only the large-scale structures of a flow are predicted while the influence of the small scales is taken into account through a model. Using the numerical tools developed, we plan to study in detail the physics of this flow-magnetic-field interaction. In particular, a careful examination of the influence of wall boundaries on the core flow will be performed. Attention will also be focused on the modification by the magnetic field of the ability of the flow to transport heat and particles. As the findings of the planned research will have a clear potential impact on different industrial activities, a particular effort will be made to find partners in industry and transfer part of the know-how gathered.]

Etude théorique et numérique de la turbulence hydrodynamique et magnetohydrodynamique [Theoretical and numerical study of hydrodynamic and magnetohydrodynamic turbulence]
Développement de simulations de grande échelle et application aux écoulements hydrodynamiques et magnetohydrodynamiques turbulents. Cette technique est basée sur une séparation d'échelles : les structures les plus petites sont modélisées alors que les plus grandes sont simulées directement. [Development of large eddy simulations and application to hydrodynamic and magnetohydrodynamic turbulent flows. This technique is based on a scale separation: The smallest structures are modelled while the largest scales are simulated directly.]


Knaepen, B. ''Cohomologie BRST locale des théories de p-formes'', Dir. M. Henneaux - LPGD, 1999


Grant EURYI 2005

disciplines et mots clés déclarés

Mécanique des fluides Métallurgie Physique Physique des plasmas Physique statistique classique et relativiste Physique théorique et mathématique

ecoulements fusion magnétohydrodinamique magnétohydrodinamique métaux liquides simulation simulation de grande échelle tokamaks turbulence