Università di Corsica Pasquale Paoli
Conférence grand public - Les ultrasons au service de la médecine | Mickael Tanter
updated
Pour en savoir plus : https://chaire-territoires.universita.corsica/arborescence.php?id_site=73&id_menu=0&id_rub=970&id_cat=646&id_art=6177&lang=fr
Pour en savoir plus : https://chaire-territoires.universita.corsica/arborescence.php?id_site=73&id_menu=0&id_rub=970&id_cat=646&id_art=6177&lang=fr
Pour en savoir plus : https://chaire-territoires.universita.corsica/arborescence.php?id_site=73&id_menu=0&id_rub=970&id_cat=646&id_art=6177&lang=fr
Pour en savoir plus : https://chaire-territoires.universita.corsica/arborescence.php?id_site=73&id_menu=0&id_rub=970&id_cat=646&id_art=6177&lang=fr
Pour en savoir plus : https://chaire-territoires.universita.corsica/arborescence.php?id_site=73&id_menu=0&id_rub=970&id_cat=646&id_art=6177&lang=fr
Pour en savoir plus : https://chaire-territoires.universita.corsica/arborescence.php?id_site=73&id_menu=0&id_rub=970&id_cat=646&id_art=6177&lang=fr
Pour en savoir plus : https://chaire-territoires.universita.corsica/arborescence.php?id_site=73&id_menu=0&id_rub=970&id_cat=646&id_art=6177&lang=fr
Pour en savoir plus : https://chaire-territoires.universita.corsica/arborescence.php?id_site=73&id_menu=0&id_rub=970&id_cat=646&id_art=6177&lang=fr
Pour en savoir plus : https://chaire-territoires.universita.corsica/arborescence.php?id_site=73&id_menu=0&id_rub=970&id_cat=646&id_art=6177&lang=fr
Organized by Ionut Danaila
The project is aimed at providing a new state-of-the-art for the mathematical-physical modelling and High Performance Computing (HPC) of Quantum Turbulence (QT) in superfluid quantum fluids, such as superfluid Helium and Bose–Einstein condensates. These are very low temperature systems in which two interpenetrating fluids exist: a normal viscous flow and an inviscid superfluid flow with quantized vortices. QT is a multiscale phenomenon for which physical models and simulations covering all scales do not exist nowadays. Our cross-disciplinary project is scoped to address theoretically and numerically the critical gap between a close-up view of the interaction between normal-fluid and quantized vortices and a coarse-grained representation of QT dynamics. The final goal is to provide a new reference HPC code simulating the global QT problem at arbitrary temperature. This topic is highly strategic for fundamental research but also for future applications promising a new technological era. More information on https://qute-hpc.math.cnrs.fr/
Pour en savoir plus sur l'Institut d'Études Scientifiques de Cargese : iesc.universita.corsica
Organized by Ionut Danaila
The project is aimed at providing a new state-of-the-art for the mathematical-physical modelling and High Performance Computing (HPC) of Quantum Turbulence (QT) in superfluid quantum fluids, such as superfluid Helium and Bose–Einstein condensates. These are very low temperature systems in which two interpenetrating fluids exist: a normal viscous flow and an inviscid superfluid flow with quantized vortices. QT is a multiscale phenomenon for which physical models and simulations covering all scales do not exist nowadays. Our cross-disciplinary project is scoped to address theoretically and numerically the critical gap between a close-up view of the interaction between normal-fluid and quantized vortices and a coarse-grained representation of QT dynamics. The final goal is to provide a new reference HPC code simulating the global QT problem at arbitrary temperature. This topic is highly strategic for fundamental research but also for future applications promising a new technological era. More information on https://qute-hpc.math.cnrs.fr/
Pour en savoir plus sur l'Institut d'Études Scientifiques de Cargese : iesc.universita.corsica
Organized by Ionut Danaila
The project is aimed at providing a new state-of-the-art for the mathematical-physical modelling and High Performance Computing (HPC) of Quantum Turbulence (QT) in superfluid quantum fluids, such as superfluid Helium and Bose–Einstein condensates. These are very low temperature systems in which two interpenetrating fluids exist: a normal viscous flow and an inviscid superfluid flow with quantized vortices. QT is a multiscale phenomenon for which physical models and simulations covering all scales do not exist nowadays. Our cross-disciplinary project is scoped to address theoretically and numerically the critical gap between a close-up view of the interaction between normal-fluid and quantized vortices and a coarse-grained representation of QT dynamics. The final goal is to provide a new reference HPC code simulating the global QT problem at arbitrary temperature. This topic is highly strategic for fundamental research but also for future applications promising a new technological era. More information on https://qute-hpc.math.cnrs.fr/
Pour en savoir plus sur l'Institut d'Études Scientifiques de Cargese : iesc.universita.corsica
Plongez dans l’univers de l’empreinte carbone ! Depuis près d’une décennie, les transporteurs aériens, maritimes et ferroviaires affichent l’impact carbone de chaque voyage. Mais que signifient réellement ces chiffres ? Quel lien avec le changement climatique ? Et surtout, comment ces déplacements se comparent-ils à nos autres activités en termes d’empreinte carbone ? Rejoignez-nous pour une conférence-découverte qui vous apportera un éclairage pédagogique sur ces questions cruciales pour le futur de l’humanité.
Organized by Ionut Danaila
The project is aimed at providing a new state-of-the-art for the mathematical-physical modelling and High Performance Computing (HPC) of Quantum Turbulence (QT) in superfluid quantum fluids, such as superfluid Helium and Bose–Einstein condensates. These are very low temperature systems in which two interpenetrating fluids exist: a normal viscous flow and an inviscid superfluid flow with quantized vortices. QT is a multiscale phenomenon for which physical models and simulations covering all scales do not exist nowadays. Our cross-disciplinary project is scoped to address theoretically and numerically the critical gap between a close-up view of the interaction between normal-fluid and quantized vortices and a coarse-grained representation of QT dynamics. The final goal is to provide a new reference HPC code simulating the global QT problem at arbitrary temperature. This topic is highly strategic for fundamental research but also for future applications promising a new technological era. More information on https://qute-hpc.math.cnrs.fr/
Pour en savoir plus sur l'Institut d'Études Scientifiques de Cargese : iesc.universita.corsica
Organized by Ionut Danaila
The project is aimed at providing a new state-of-the-art for the mathematical-physical modelling and High Performance Computing (HPC) of Quantum Turbulence (QT) in superfluid quantum fluids, such as superfluid Helium and Bose–Einstein condensates. These are very low temperature systems in which two interpenetrating fluids exist: a normal viscous flow and an inviscid superfluid flow with quantized vortices. QT is a multiscale phenomenon for which physical models and simulations covering all scales do not exist nowadays. Our cross-disciplinary project is scoped to address theoretically and numerically the critical gap between a close-up view of the interaction between normal-fluid and quantized vortices and a coarse-grained representation of QT dynamics. The final goal is to provide a new reference HPC code simulating the global QT problem at arbitrary temperature. This topic is highly strategic for fundamental research but also for future applications promising a new technological era. More information on https://qute-hpc.math.cnrs.fr/
Pour en savoir plus sur l'Institut d'Études Scientifiques de Cargese : iesc.universita.corsica
Organized by Ionut Danaila
The project is aimed at providing a new state-of-the-art for the mathematical-physical modelling and High Performance Computing (HPC) of Quantum Turbulence (QT) in superfluid quantum fluids, such as superfluid Helium and Bose–Einstein condensates. These are very low temperature systems in which two interpenetrating fluids exist: a normal viscous flow and an inviscid superfluid flow with quantized vortices. QT is a multiscale phenomenon for which physical models and simulations covering all scales do not exist nowadays. Our cross-disciplinary project is scoped to address theoretically and numerically the critical gap between a close-up view of the interaction between normal-fluid and quantized vortices and a coarse-grained representation of QT dynamics. The final goal is to provide a new reference HPC code simulating the global QT problem at arbitrary temperature. This topic is highly strategic for fundamental research but also for future applications promising a new technological era. More information on https://qute-hpc.math.cnrs.fr/
Pour en savoir plus sur l'Institut d'Études Scientifiques de Cargese : iesc.universita.corsica
Organized by Ionut Danaila
The project is aimed at providing a new state-of-the-art for the mathematical-physical modelling and High Performance Computing (HPC) of Quantum Turbulence (QT) in superfluid quantum fluids, such as superfluid Helium and Bose–Einstein condensates. These are very low temperature systems in which two interpenetrating fluids exist: a normal viscous flow and an inviscid superfluid flow with quantized vortices. QT is a multiscale phenomenon for which physical models and simulations covering all scales do not exist nowadays. Our cross-disciplinary project is scoped to address theoretically and numerically the critical gap between a close-up view of the interaction between normal-fluid and quantized vortices and a coarse-grained representation of QT dynamics. The final goal is to provide a new reference HPC code simulating the global QT problem at arbitrary temperature. This topic is highly strategic for fundamental research but also for future applications promising a new technological era. More information on https://qute-hpc.math.cnrs.fr/
Pour en savoir plus sur l'Institut d'Études Scientifiques de Cargese : iesc.universita.corsica
Organized by Ionut Danaila
The project is aimed at providing a new state-of-the-art for the mathematical-physical modelling and High Performance Computing (HPC) of Quantum Turbulence (QT) in superfluid quantum fluids, such as superfluid Helium and Bose–Einstein condensates. These are very low temperature systems in which two interpenetrating fluids exist: a normal viscous flow and an inviscid superfluid flow with quantized vortices. QT is a multiscale phenomenon for which physical models and simulations covering all scales do not exist nowadays. Our cross-disciplinary project is scoped to address theoretically and numerically the critical gap between a close-up view of the interaction between normal-fluid and quantized vortices and a coarse-grained representation of QT dynamics. The final goal is to provide a new reference HPC code simulating the global QT problem at arbitrary temperature. This topic is highly strategic for fundamental research but also for future applications promising a new technological era. More information on https://qute-hpc.math.cnrs.fr/
Pour en savoir plus sur l'Institut d'Études Scientifiques de Cargese : iesc.universita.corsica
Organized by Ionut Danaila
The project is aimed at providing a new state-of-the-art for the mathematical-physical modelling and High Performance Computing (HPC) of Quantum Turbulence (QT) in superfluid quantum fluids, such as superfluid Helium and Bose–Einstein condensates. These are very low temperature systems in which two interpenetrating fluids exist: a normal viscous flow and an inviscid superfluid flow with quantized vortices. QT is a multiscale phenomenon for which physical models and simulations covering all scales do not exist nowadays. Our cross-disciplinary project is scoped to address theoretically and numerically the critical gap between a close-up view of the interaction between normal-fluid and quantized vortices and a coarse-grained representation of QT dynamics. The final goal is to provide a new reference HPC code simulating the global QT problem at arbitrary temperature. This topic is highly strategic for fundamental research but also for future applications promising a new technological era. More information on https://qute-hpc.math.cnrs.fr/
Pour en savoir plus sur l'Institut d'Études Scientifiques de Cargese : iesc.universita.corsica
Organized by Ionut Danaila
The project is aimed at providing a new state-of-the-art for the mathematical-physical modelling and High Performance Computing (HPC) of Quantum Turbulence (QT) in superfluid quantum fluids, such as superfluid Helium and Bose–Einstein condensates. These are very low temperature systems in which two interpenetrating fluids exist: a normal viscous flow and an inviscid superfluid flow with quantized vortices. QT is a multiscale phenomenon for which physical models and simulations covering all scales do not exist nowadays. Our cross-disciplinary project is scoped to address theoretically and numerically the critical gap between a close-up view of the interaction between normal-fluid and quantized vortices and a coarse-grained representation of QT dynamics. The final goal is to provide a new reference HPC code simulating the global QT problem at arbitrary temperature. This topic is highly strategic for fundamental research but also for future applications promising a new technological era. More information on https://qute-hpc.math.cnrs.fr/
Pour en savoir plus sur l'Institut d'Études Scientifiques de Cargese : iesc.universita.corsica
Organized by Ionut Danaila
The project is aimed at providing a new state-of-the-art for the mathematical-physical modelling and High Performance Computing (HPC) of Quantum Turbulence (QT) in superfluid quantum fluids, such as superfluid Helium and Bose–Einstein condensates. These are very low temperature systems in which two interpenetrating fluids exist: a normal viscous flow and an inviscid superfluid flow with quantized vortices. QT is a multiscale phenomenon for which physical models and simulations covering all scales do not exist nowadays. Our cross-disciplinary project is scoped to address theoretically and numerically the critical gap between a close-up view of the interaction between normal-fluid and quantized vortices and a coarse-grained representation of QT dynamics. The final goal is to provide a new reference HPC code simulating the global QT problem at arbitrary temperature. This topic is highly strategic for fundamental research but also for future applications promising a new technological era. More information on https://qute-hpc.math.cnrs.fr/
Pour en savoir plus sur l'Institut d'Études Scientifiques de Cargese : iesc.universita.corsica
Organized by Ionut Danaila
The project is aimed at providing a new state-of-the-art for the mathematical-physical modelling and High Performance Computing (HPC) of Quantum Turbulence (QT) in superfluid quantum fluids, such as superfluid Helium and Bose–Einstein condensates. These are very low temperature systems in which two interpenetrating fluids exist: a normal viscous flow and an inviscid superfluid flow with quantized vortices. QT is a multiscale phenomenon for which physical models and simulations covering all scales do not exist nowadays. Our cross-disciplinary project is scoped to address theoretically and numerically the critical gap between a close-up view of the interaction between normal-fluid and quantized vortices and a coarse-grained representation of QT dynamics. The final goal is to provide a new reference HPC code simulating the global QT problem at arbitrary temperature. This topic is highly strategic for fundamental research but also for future applications promising a new technological era. More information on https://qute-hpc.math.cnrs.fr/
Pour en savoir plus sur l'Institut d'Études Scientifiques de Cargese : iesc.universita.corsica
Organized by Ionut Danaila The project is aimed at providing a new state-of-the-art for the mathematical-physical modelling and High Performance Computing (HPC) of Quantum Turbulence (QT) in superfluid quantum fluids, such as superfluid Helium and Bose–Einstein condensates. These are very low temperature systems in which two interpenetrating fluids exist: a normal viscous flow and an inviscid superfluid flow with quantized vortices. QT is a multiscale phenomenon for which physical models and simulations covering all scales do not exist nowadays. Our cross-disciplinary project is scoped to address theoretically and numerically the critical gap between a close-up view of the interaction between normal-fluid and quantized vortices and a coarse-grained representation of QT dynamics. The final goal is to provide a new reference HPC code simulating the global QT problem at arbitrary temperature. This topic is highly strategic for fundamental research but also for future applications promising a new technological era. More information on https://qute-hpc.math.cnrs.fr/
Pour en savoir plus sur l'Institut d'Études Scientifiques de Cargese : iesc.universita.corsica
Organized by Ionut Danaila The project is aimed at providing a new state-of-the-art for the mathematical-physical modelling and High Performance Computing (HPC) of Quantum Turbulence (QT) in superfluid quantum fluids, such as superfluid Helium and Bose–Einstein condensates. These are very low temperature systems in which two interpenetrating fluids exist: a normal viscous flow and an inviscid superfluid flow with quantized vortices. QT is a multiscale phenomenon for which physical models and simulations covering all scales do not exist nowadays. Our cross-disciplinary project is scoped to address theoretically and numerically the critical gap between a close-up view of the interaction between normal-fluid and quantized vortices and a coarse-grained representation of QT dynamics. The final goal is to provide a new reference HPC code simulating the global QT problem at arbitrary temperature. This topic is highly strategic for fundamental research but also for future applications promising a new technological era. More information on https://qute-hpc.math.cnrs.fr/
Pour en savoir plus sur l'Institut d'Études Scientifiques de Cargese : iesc.universita.corsica
Organized by Ionut Danaila
The project is aimed at providing a new state-of-the-art for the mathematical-physical modelling and High Performance Computing (HPC) of Quantum Turbulence (QT) in superfluid quantum fluids, such as superfluid Helium and Bose–Einstein condensates.
These are very low temperature systems in which two interpenetrating fluids exist: a normal viscous flow and an inviscid superfluid flow with quantized vortices. QT is a multiscale phenomenon for which physical models and simulations covering all scales do not exist nowadays. Our cross-disciplinary project is scoped to address theoretically and numerically the critical gap between a close-up view of the interaction between normal-fluid and quantized vortices and a coarse-grained representation of QT dynamics. The final goal is to provide a new reference HPC code simulating the global QT problem at arbitrary temperature. This topic is highly strategic for fundamental research but also for future applications promising a new technological era.
More information on https://qute-hpc.math.cnrs.fr/
Pour en savoir plus sur l'Institut d'Études Scientifiques de Cargese : iesc.universita.corsica
Interfreeze : Freezing and Interfaces
Organized by S.Bandeira,T. Seon, C.Josserand, A.Huerre, J.Pierre
The objective of this school is to present the fundamentals and the latest theoretical advances and experimental activities in the field of solidification of capillary flows, porous media and heterogeneous mixtures, with a particular focus on the case of ice formation. This is an emerging subject in the macroscopic physics community, older in others (metallurgy for example), and crucial in a wide range of applications from aeronautics to environmental issues. The aim of this school is therefore to train these different communities together, but also to structure them and generate synergy between the main national and international players in these fields.
Le développement technologique a permis à l’astrophysique de connaître un essor sans précédent depuis la deuxième moitié du vingtième siècle.
Afin d’illustrer certains de ces progrès et d’évoquer certains thèmes majeurs de la recherche en sciences de l’Univers, cette conférence retracera une découverte récente : l’origine céleste de l’Or, ou la nature extraordinaire des chaudrons cosmiques dans lesquels cet élément chimique trouve son origine.
La résidence, dans sa nouvelle version, n'est en effet plus organisée seulement autour d'un matériau local, mais par de nouveaux usages des objets.
Réalisation: Luana Ida-Cerne
Première assistante réalisatrice: Louna Saïdi
Cheffe Opératrice / Etalonneuse: Luana Ida-Cerne
Ingénieur du son: Dylan Rolos-Leoni
Directeur de production: Lilian Dantot
Régisseuse générale: Emma Laurent
Régisseuse adjointe: Louise Ben Salem-Knapp
Monteur: Quentin Pietri
Assistant monteur: Alexey Tsvetkov
Monteur son: Dylan Rolos-Leoni
Musique: Pots and Pan Beats - Household Percussion/Drumming (By Rythm me This)
Organized by Ionut Danaila
The project is aimed at providing a new state-of-the-art for the mathematical-physical modelling and High Performance Computing (HPC) of Quantum Turbulence (QT) in superfluid quantum fluids, such as superfluid Helium and Bose–Einstein condensates.
These are very low temperature systems in which two interpenetrating fluids exist: a normal viscous flow and an inviscid superfluid flow with quantized vortices. QT is a multiscale phenomenon for which physical models and simulations covering all scales do not exist nowadays. Our cross-disciplinary project is scoped to address theoretically and numerically the critical gap between a close-up view of the interaction between normal-fluid and quantized vortices and a coarse-grained representation of QT dynamics. The final goal is to provide a new reference HPC code simulating the global QT problem at arbitrary temperature. This topic is highly strategic for fundamental research but also for future applications promising a new technological era.
More information on https://qute-hpc.math.cnrs.fr/
Pour en savoir plus sur l'Institut d'Études Scientifiques de Cargese : iesc.universita.corsica
Organized by Ionut Danaila
The project is aimed at providing a new state-of-the-art for the mathematical-physical modelling and High Performance Computing (HPC) of Quantum Turbulence (QT) in superfluid quantum fluids, such as superfluid Helium and Bose–Einstein condensates.
These are very low temperature systems in which two interpenetrating fluids exist: a normal viscous flow and an inviscid superfluid flow with quantized vortices. QT is a multiscale phenomenon for which physical models and simulations covering all scales do not exist nowadays. Our cross-disciplinary project is scoped to address theoretically and numerically the critical gap between a close-up view of the interaction between normal-fluid and quantized vortices and a coarse-grained representation of QT dynamics. The final goal is to provide a new reference HPC code simulating the global QT problem at arbitrary temperature. This topic is highly strategic for fundamental research but also for future applications promising a new technological era.
More information on https://qute-hpc.math.cnrs.fr/
Pour en savoir plus sur l'Institut d'Études Scientifiques de Cargese : iesc.universita.corsica
Organized by Ionut Danaila
The project is aimed at providing a new state-of-the-art for the mathematical-physical modelling and High Performance Computing (HPC) of Quantum Turbulence (QT) in superfluid quantum fluids, such as superfluid Helium and Bose–Einstein condensates.
These are very low temperature systems in which two interpenetrating fluids exist: a normal viscous flow and an inviscid superfluid flow with quantized vortices. QT is a multiscale phenomenon for which physical models and simulations covering all scales do not exist nowadays. Our cross-disciplinary project is scoped to address theoretically and numerically the critical gap between a close-up view of the interaction between normal-fluid and quantized vortices and a coarse-grained representation of QT dynamics. The final goal is to provide a new reference HPC code simulating the global QT problem at arbitrary temperature. This topic is highly strategic for fundamental research but also for future applications promising a new technological era.
More information on https://qute-hpc.math.cnrs.fr/
Pour en savoir plus sur l'Institut d'Études Scientifiques de Cargese : iesc.universita.corsica
Organized by Ionut Danaila
The project is aimed at providing a new state-of-the-art for the mathematical-physical modelling and High Performance Computing (HPC) of Quantum Turbulence (QT) in superfluid quantum fluids, such as superfluid Helium and Bose–Einstein condensates.
These are very low temperature systems in which two interpenetrating fluids exist: a normal viscous flow and an inviscid superfluid flow with quantized vortices. QT is a multiscale phenomenon for which physical models and simulations covering all scales do not exist nowadays. Our cross-disciplinary project is scoped to address theoretically and numerically the critical gap between a close-up view of the interaction between normal-fluid and quantized vortices and a coarse-grained representation of QT dynamics. The final goal is to provide a new reference HPC code simulating the global QT problem at arbitrary temperature. This topic is highly strategic for fundamental research but also for future applications promising a new technological era.
More information on https://qute-hpc.math.cnrs.fr/
Pour en savoir plus sur l'Institut d'Études Scientifiques de Cargese : iesc.universita.corsica
Organized by Ionut Danaila
The project is aimed at providing a new state-of-the-art for the mathematical-physical modelling and High Performance Computing (HPC) of Quantum Turbulence (QT) in superfluid quantum fluids, such as superfluid Helium and Bose–Einstein condensates.
These are very low temperature systems in which two interpenetrating fluids exist: a normal viscous flow and an inviscid superfluid flow with quantized vortices. QT is a multiscale phenomenon for which physical models and simulations covering all scales do not exist nowadays. Our cross-disciplinary project is scoped to address theoretically and numerically the critical gap between a close-up view of the interaction between normal-fluid and quantized vortices and a coarse-grained representation of QT dynamics. The final goal is to provide a new reference HPC code simulating the global QT problem at arbitrary temperature. This topic is highly strategic for fundamental research but also for future applications promising a new technological era.
More information on https://qute-hpc.math.cnrs.fr/
Pour en savoir plus sur l'Institut d'Études Scientifiques de Cargese : iesc.universita.corsica
Organized by Ionut Danaila
The project is aimed at providing a new state-of-the-art for the mathematical-physical modelling and High Performance Computing (HPC) of Quantum Turbulence (QT) in superfluid quantum fluids, such as superfluid Helium and Bose–Einstein condensates.
These are very low temperature systems in which two interpenetrating fluids exist: a normal viscous flow and an inviscid superfluid flow with quantized vortices. QT is a multiscale phenomenon for which physical models and simulations covering all scales do not exist nowadays. Our cross-disciplinary project is scoped to address theoretically and numerically the critical gap between a close-up view of the interaction between normal-fluid and quantized vortices and a coarse-grained representation of QT dynamics. The final goal is to provide a new reference HPC code simulating the global QT problem at arbitrary temperature. This topic is highly strategic for fundamental research but also for future applications promising a new technological era.
More information on https://qute-hpc.math.cnrs.fr/
Pour en savoir plus sur l'Institut d'Études Scientifiques de Cargese : iesc.universita.corsica
Organized by Ionut Danaila
The project is aimed at providing a new state-of-the-art for the mathematical-physical modelling and High Performance Computing (HPC) of Quantum Turbulence (QT) in superfluid quantum fluids, such as superfluid Helium and Bose–Einstein condensates.
These are very low temperature systems in which two interpenetrating fluids exist: a normal viscous flow and an inviscid superfluid flow with quantized vortices. QT is a multiscale phenomenon for which physical models and simulations covering all scales do not exist nowadays. Our cross-disciplinary project is scoped to address theoretically and numerically the critical gap between a close-up view of the interaction between normal-fluid and quantized vortices and a coarse-grained representation of QT dynamics. The final goal is to provide a new reference HPC code simulating the global QT problem at arbitrary temperature. This topic is highly strategic for fundamental research but also for future applications promising a new technological era.
More information on https://qute-hpc.math.cnrs.fr/
Pour en savoir plus sur l'Institut d'Études Scientifiques de Cargese : iesc.universita.corsica
Organized by Ionut Danaila
The project is aimed at providing a new state-of-the-art for the mathematical-physical modelling and High Performance Computing (HPC) of Quantum Turbulence (QT) in superfluid quantum fluids, such as superfluid Helium and Bose–Einstein condensates.
These are very low temperature systems in which two interpenetrating fluids exist: a normal viscous flow and an inviscid superfluid flow with quantized vortices. QT is a multiscale phenomenon for which physical models and simulations covering all scales do not exist nowadays. Our cross-disciplinary project is scoped to address theoretically and numerically the critical gap between a close-up view of the interaction between normal-fluid and quantized vortices and a coarse-grained representation of QT dynamics. The final goal is to provide a new reference HPC code simulating the global QT problem at arbitrary temperature. This topic is highly strategic for fundamental research but also for future applications promising a new technological era.
More information on https://qute-hpc.math.cnrs.fr/
Pour en savoir plus sur l'Institut d'Études Scientifiques de Cargese : iesc.universita.corsica
Organized by Ionut Danaila
The project is aimed at providing a new state-of-the-art for the mathematical-physical modelling and High Performance Computing (HPC) of Quantum Turbulence (QT) in superfluid quantum fluids, such as superfluid Helium and Bose–Einstein condensates.
These are very low temperature systems in which two interpenetrating fluids exist: a normal viscous flow and an inviscid superfluid flow with quantized vortices. QT is a multiscale phenomenon for which physical models and simulations covering all scales do not exist nowadays. Our cross-disciplinary project is scoped to address theoretically and numerically the critical gap between a close-up view of the interaction between normal-fluid and quantized vortices and a coarse-grained representation of QT dynamics. The final goal is to provide a new reference HPC code simulating the global QT problem at arbitrary temperature. This topic is highly strategic for fundamental research but also for future applications promising a new technological era.
More information on https://qute-hpc.math.cnrs.fr/
Pour en savoir plus sur l'Institut d'Études Scientifiques de Cargese : iesc.universita.corsica
Organized by Ionut Danaila
The project is aimed at providing a new state-of-the-art for the mathematical-physical modelling and High Performance Computing (HPC) of Quantum Turbulence (QT) in superfluid quantum fluids, such as superfluid Helium and Bose–Einstein condensates.
These are very low temperature systems in which two interpenetrating fluids exist: a normal viscous flow and an inviscid superfluid flow with quantized vortices. QT is a multiscale phenomenon for which physical models and simulations covering all scales do not exist nowadays. Our cross-disciplinary project is scoped to address theoretically and numerically the critical gap between a close-up view of the interaction between normal-fluid and quantized vortices and a coarse-grained representation of QT dynamics. The final goal is to provide a new reference HPC code simulating the global QT problem at arbitrary temperature. This topic is highly strategic for fundamental research but also for future applications promising a new technological era.
More information on https://qute-hpc.math.cnrs.fr/
Pour en savoir plus sur l'Institut d'Études Scientifiques de Cargese : iesc.universita.corsica
Organized by Ionut Danaila
The project is aimed at providing a new state-of-the-art for the mathematical-physical modelling and High Performance Computing (HPC) of Quantum Turbulence (QT) in superfluid quantum fluids, such as superfluid Helium and Bose–Einstein condensates.
These are very low temperature systems in which two interpenetrating fluids exist: a normal viscous flow and an inviscid superfluid flow with quantized vortices. QT is a multiscale phenomenon for which physical models and simulations covering all scales do not exist nowadays. Our cross-disciplinary project is scoped to address theoretically and numerically the critical gap between a close-up view of the interaction between normal-fluid and quantized vortices and a coarse-grained representation of QT dynamics. The final goal is to provide a new reference HPC code simulating the global QT problem at arbitrary temperature. This topic is highly strategic for fundamental research but also for future applications promising a new technological era.
More information on https://qute-hpc.math.cnrs.fr/
Pour en savoir plus sur l'Institut d'Études Scientifiques de Cargese : iesc.universita.corsica
"This advanced summer school aims at researchers and PhD students. The main motivation is to gather and promote exchanges between the theoretical mathematical developments on fluids and the more applied mathematics. The theme for this school is `water waves: dispersion, travelling waves, vorticity'. The first week will be devoted to `vortices' and the second week to `water waves'."
Pour en savoir plus sur l'Institut d'Études Scientifiques de Cargese : iesc.universita.corsica
"This advanced summer school aims at researchers and PhD students. The main motivation is to gather and promote exchanges between the theoretical mathematical developments on fluids and the more applied mathematics. The theme for this school is `water waves: dispersion, travelling waves, vorticity'. The first week will be devoted to `vortices' and the second week to `water waves'."
Pour en savoir plus sur l'Institut d'Études Scientifiques de Cargese : iesc.universita.corsica
"This advanced summer school aims at researchers and PhD students. The main motivation is to gather and promote exchanges between the theoretical mathematical developments on fluids and the more applied mathematics. The theme for this school is `water waves: dispersion, travelling waves, vorticity'. The first week will be devoted to `vortices' and the second week to `water waves'."
Pour en savoir plus sur l'Institut d'Études Scientifiques de Cargese : iesc.universita.corsica
"This advanced summer school aims at researchers and PhD students. The main motivation is to gather and promote exchanges between the theoretical mathematical developments on fluids and the more applied mathematics. The theme for this school is `water waves: dispersion, travelling waves, vorticity'. The first week will be devoted to `vortices' and the second week to `water waves'."
Pour en savoir plus sur l'Institut d'Études Scientifiques de Cargese : iesc.universita.corsica