The statistical properties of turbulence differ in an essential way from those of systems in or near thermal equilibrium because of the flux of energy between vastly different scales at which energy is supplied and at which it is dissipated. We elucidate this difference by studying experimentally and numerically the fluctuations of the energy of a small fluid particle moving in a turbulent fluid. We demonstrate how the fundamental property of detailed balance is broken, so that the probabilities of forward and backward transitions are not equal for turbulence. In physical terms, we found that in a large set of flow configurations, fluid elements decelerate faster than accelerate, a feature known all too well from driving in dense traffic. T...
In this paper, we consider a simplified model of turbulence for large Reynolds numbers driven by a c...
Turbulence prevails in the universe, and its multi-scale properties affect the global dynamics of ge...
We compare experiments and direct numerical simulations to evaluate the accuracy of the Stokes-drag ...
In 3D turbulent flows, the direct cascade of energy, characterized by a flux through scales, ε, is a...
International audienceMany turbulent flows undergo drastic and abrupt configuration changes with hug...
Experiment 1 studies finite system size effects on temporal energy flux fluctuations in three-dimens...
We address the experimentally observed non-Gaussian fluctuations for the energy injected into a clos...
International audienceo answer the question whether a cascade of energy exists or not in turbulenc...
We present an extensive numerical study of the time irreversibility of the dynamics of heavy inertia...
Turbulence is a ubiquitous state for many flows in nature and engineering. As the flow velocity is i...
International audienceWe investigate experimentally three-dimensional (3D) hydrodynamic turbulence a...
Results from Direct Numerical Simulations of particle relative dispersion in three dimensional homog...
International audienceThe three-dimensional incompressible Navier–Stokes equations, which describe t...
In this paper, we consider a simplified model of turbulence for large Reynolds numbers driven by a c...
Turbulence prevails in the universe, and its multi-scale properties affect the global dynamics of ge...
We compare experiments and direct numerical simulations to evaluate the accuracy of the Stokes-drag ...
In 3D turbulent flows, the direct cascade of energy, characterized by a flux through scales, ε, is a...
International audienceMany turbulent flows undergo drastic and abrupt configuration changes with hug...
Experiment 1 studies finite system size effects on temporal energy flux fluctuations in three-dimens...
We address the experimentally observed non-Gaussian fluctuations for the energy injected into a clos...
International audienceo answer the question whether a cascade of energy exists or not in turbulenc...
We present an extensive numerical study of the time irreversibility of the dynamics of heavy inertia...
Turbulence is a ubiquitous state for many flows in nature and engineering. As the flow velocity is i...
International audienceWe investigate experimentally three-dimensional (3D) hydrodynamic turbulence a...
Results from Direct Numerical Simulations of particle relative dispersion in three dimensional homog...
International audienceThe three-dimensional incompressible Navier–Stokes equations, which describe t...
In this paper, we consider a simplified model of turbulence for large Reynolds numbers driven by a c...
Turbulence prevails in the universe, and its multi-scale properties affect the global dynamics of ge...
We compare experiments and direct numerical simulations to evaluate the accuracy of the Stokes-drag ...