Producción CientíficaA study of the distribution of energy among the different scales is performed for several systems in fluid mechanics, including the Navier–Stokes, magnetohydrodynamics and active scalars equations. It is found that all these systems possess a common structure which enables us to deduce how the energy introduced by the forcing is transferred to the scales present in the flow. It is also shown that in special cases an energy cascade will occur. The limits of this method are also considered
Kelvin's Theorem on conservation of circulations is an essential ingredient of G. I. Taylor's theory...
The present work describes the multidimensional behaviour of scale-energy production, transfer and d...
The generalised Kolmogorov equation is used to describe the scale-by-scale turbulence dynamics in ...
An up-to-date comprehensive text useful for graduate students and academic researchers in the field ...
International audienceAn important characteristic of geophysically turbulent flows is the transfer o...
A temporal study of energy transfer across length scales is performed in 3D numerical simulations of...
It is theoretically established that energy transfer in nonhomogeneous turbulence occurs in two dist...
Astrophysical flows span a broad range of scales and thus require sub-grid modeling. We compute the ...
We analyze the fluctuations of the dissipated energy in a simple and general model where dissipation...
Turbulent flows are characterized by the non-linear cascades of energy and other inviscid invariant...
Energy transfer plays an essential role in many natural and engineering processes which include diff...
The defining characteristic of turbulent flows is their ability to dissipate energy, even in the lim...
We analyse the inter-scale transfer of energy for two types of plane Poiseuille flow: the P4U exact ...
True dissipation occurs mainly at the highest wavenumbers where the eddy sizes are comparatively sma...
International audienceWe study experimentally the influence of dissipation on stationary capillary w...
Kelvin's Theorem on conservation of circulations is an essential ingredient of G. I. Taylor's theory...
The present work describes the multidimensional behaviour of scale-energy production, transfer and d...
The generalised Kolmogorov equation is used to describe the scale-by-scale turbulence dynamics in ...
An up-to-date comprehensive text useful for graduate students and academic researchers in the field ...
International audienceAn important characteristic of geophysically turbulent flows is the transfer o...
A temporal study of energy transfer across length scales is performed in 3D numerical simulations of...
It is theoretically established that energy transfer in nonhomogeneous turbulence occurs in two dist...
Astrophysical flows span a broad range of scales and thus require sub-grid modeling. We compute the ...
We analyze the fluctuations of the dissipated energy in a simple and general model where dissipation...
Turbulent flows are characterized by the non-linear cascades of energy and other inviscid invariant...
Energy transfer plays an essential role in many natural and engineering processes which include diff...
The defining characteristic of turbulent flows is their ability to dissipate energy, even in the lim...
We analyse the inter-scale transfer of energy for two types of plane Poiseuille flow: the P4U exact ...
True dissipation occurs mainly at the highest wavenumbers where the eddy sizes are comparatively sma...
International audienceWe study experimentally the influence of dissipation on stationary capillary w...
Kelvin's Theorem on conservation of circulations is an essential ingredient of G. I. Taylor's theory...
The present work describes the multidimensional behaviour of scale-energy production, transfer and d...
The generalised Kolmogorov equation is used to describe the scale-by-scale turbulence dynamics in ...