Add to ORKGThe kinetic theory of gases provides methods for calculating Lyapunov exponents and other quantities, such as Kolmogorov-Sinai entropies, that characterize the chaotic behavior of hard-ball gases. Here we illustrate the use of these methods for calculating the Kolmogorov-Sinai entropy, and the largest positive Lyapunov exponent, for dilute hard-ball gases in equilibrium. The calculation of the largest Lyapunov exponent makes interesting connections with the theory of propagation of hydrodynamic fronts. Calculations are also presented for the Lyapunov spectrum of dilute, random Lorentz gases in two and three dimensions, which are considerably simpler than the corresponding calculations for hard-ball gases. The article concludes with...
We calculate the maximal Lyapunov exponent, the generalized entropies, the asymptotic distance betwe...
Entropy and entropy production have recently become mathematical tools for kinetic and hydrodynamic ...
Contains fulltext : 83797.pdf (preprint version ) (Open Access)8 p
It is generally believed that the dynamics of simple fluids can be considered to be chaotic, at lea...
We compute the Lyapunov spectrum and the Kolmogorov-Sinai entropy for a moving particle placed in a ...
We consider the density expansion of the Kolmogorov-Sinai (KS) entropy per particle for a dilute gas...
In this thesis I discuss some of the chaotic properties specific to systems of many particles and o...
A kinetic approach is adopted to describe the exponential growth of a small deviation of the initial...
We present a (mostly) rigorous approach to unbounded and bounded (open) dilute random Lorentz gases....
In classical chaotic systems the entropy, averaged over initial phase space distributions, follows a...
A non-vanishing Lyapunov exponent 1 provides the very definition of deterministic chaos in the solu...
Entropy and entropy production have recently become mathematical tools for kinetic and hydrodynamic ...
Since several years Lyapunov Characteristic Exponents are of interest in the study of dynamical syst...
Lyapunov spectra are measured for a three-dimensional many-body dense fluid. not only at equilibrium...
We study chaos in the Hamiltonian Mean Field model (HMF), a system with many degrees of freedom in w...
We calculate the maximal Lyapunov exponent, the generalized entropies, the asymptotic distance betwe...
Entropy and entropy production have recently become mathematical tools for kinetic and hydrodynamic ...
Contains fulltext : 83797.pdf (preprint version ) (Open Access)8 p
It is generally believed that the dynamics of simple fluids can be considered to be chaotic, at lea...
We compute the Lyapunov spectrum and the Kolmogorov-Sinai entropy for a moving particle placed in a ...
We consider the density expansion of the Kolmogorov-Sinai (KS) entropy per particle for a dilute gas...
In this thesis I discuss some of the chaotic properties specific to systems of many particles and o...
A kinetic approach is adopted to describe the exponential growth of a small deviation of the initial...
We present a (mostly) rigorous approach to unbounded and bounded (open) dilute random Lorentz gases....
In classical chaotic systems the entropy, averaged over initial phase space distributions, follows a...
A non-vanishing Lyapunov exponent 1 provides the very definition of deterministic chaos in the solu...
Entropy and entropy production have recently become mathematical tools for kinetic and hydrodynamic ...
Since several years Lyapunov Characteristic Exponents are of interest in the study of dynamical syst...
Lyapunov spectra are measured for a three-dimensional many-body dense fluid. not only at equilibrium...
We study chaos in the Hamiltonian Mean Field model (HMF), a system with many degrees of freedom in w...
We calculate the maximal Lyapunov exponent, the generalized entropies, the asymptotic distance betwe...
Entropy and entropy production have recently become mathematical tools for kinetic and hydrodynamic ...
Contains fulltext : 83797.pdf (preprint version ) (Open Access)8 p