International audienceThis paper discusses the application of Lyapunov theory in chaotic systems to the dynamics of tracer gradients in two-dimensional flows. The Lyapunov theory indicates that more attention should be given to the Lyapunov vector orientation. Moreover, the properties of Lyapunov vectors and exponents are explained in light of recent results on tracer gradients dynamics. Differences between the different Lyapunov vectors can be interpreted in terms of competition between the effects of effective rotation and strain. Also, the differences between backward and forward vectors give information on the local reversibility of the tracer gradient dynamics. A numerical simulation of two-dimensional turbulence serves to highlight th...
We present an investigation of the Lyapunov spectrum of the chaotic, separated flow around the NACA ...
Lyapunov exponents lie at the heart of chaos theory, and are widely used in studies of complex dynam...
Using a multi-scaled, chaotic flow known as the KS model of turbulence [J.C.H. Fung, J.C.R. Hunt, A....
International audienceThis paper discusses the application of Lyapunov theory in chaotic systems to ...
In the context of the analysis of the chaotic properties of homogeneous and isotropic turbulence, di...
Lyapunov exponents of heavy particles and tracers advected by homogeneous and isotropic turbulent fl...
The statistics of the Finite time Lyapunov exponent (FTLE) has been investigated in detail in labora...
We study the motion of small particles in a random turbulent. flow assuming a linear law of friction...
The present work analyzes the statistics of finite scale local Lyapunov exponents of pairs of fluid ...
We investigate the impact of numerical discretization on the Lyapunov spectrum of separated flow sim...
Lagrangian motion in a quasi-two-dimensional, time-dependent, convective flow is studied at differen...
This paper develops the theory and computation of Lagrangian Coherent Structures (LCS), which are de...
The purpose of this brief comunication is to improve the hypothesis of the previous work of the auth...
International audienceThis paper investigates the dynamics of tracer gradient for a two-dimensional ...
The purpose of this paper is to improve a hypothesis of the previous work of N. de Divitiis (2011) d...
We present an investigation of the Lyapunov spectrum of the chaotic, separated flow around the NACA ...
Lyapunov exponents lie at the heart of chaos theory, and are widely used in studies of complex dynam...
Using a multi-scaled, chaotic flow known as the KS model of turbulence [J.C.H. Fung, J.C.R. Hunt, A....
International audienceThis paper discusses the application of Lyapunov theory in chaotic systems to ...
In the context of the analysis of the chaotic properties of homogeneous and isotropic turbulence, di...
Lyapunov exponents of heavy particles and tracers advected by homogeneous and isotropic turbulent fl...
The statistics of the Finite time Lyapunov exponent (FTLE) has been investigated in detail in labora...
We study the motion of small particles in a random turbulent. flow assuming a linear law of friction...
The present work analyzes the statistics of finite scale local Lyapunov exponents of pairs of fluid ...
We investigate the impact of numerical discretization on the Lyapunov spectrum of separated flow sim...
Lagrangian motion in a quasi-two-dimensional, time-dependent, convective flow is studied at differen...
This paper develops the theory and computation of Lagrangian Coherent Structures (LCS), which are de...
The purpose of this brief comunication is to improve the hypothesis of the previous work of the auth...
International audienceThis paper investigates the dynamics of tracer gradient for a two-dimensional ...
The purpose of this paper is to improve a hypothesis of the previous work of N. de Divitiis (2011) d...
We present an investigation of the Lyapunov spectrum of the chaotic, separated flow around the NACA ...
Lyapunov exponents lie at the heart of chaos theory, and are widely used in studies of complex dynam...
Using a multi-scaled, chaotic flow known as the KS model of turbulence [J.C.H. Fung, J.C.R. Hunt, A....