Add to ORKGIn this article the linear Boltzmann equation is derived for a particle interacting with a Gaussian random field, in the weak coupling limit, with renewal in time of the random field. The initial data can be chosen arbitrarily. The proof is geometric and involves coherent states and semi-classical calculus
to appear, Annals of PDEsInternational audienceWe derive the linear acoustic and Stokes-Fourier equa...
The Boltzmann equation is widely used in describing the time evolution of a rarefied gas of particle...
We investigate the far-from-equilibrium behavior of the Boltzmann equation for a gas of massless sca...
The derivation of a kinetic equation is the justification from a microscopic model describing a give...
We study the time evolution of a quantum particle in a Gaussian random environment. We show that in ...
A large system of particles is studied. Its time evolution is determined as the superposition of two...
La dérivation d'équations cinétiques consiste à obtenir, à partir d'un modèle microscopique décrivan...
. In this paper we consider a particle moving in a random distribution of obstacles. Each obstacle g...
AbstractWe consider the problem of deriving the linear Boltzmann equation from the Lorentz process w...
A measure of deviation from equilibrium of an ensemble of particles is proposed, which is physically...
We consider the problem of deriving the linear Boltzmann equation from the Lorentz process with hard...
AbstractWe study in this article the transport of particles in time-dependent random media, in the s...
Boltzmann-Gibbs random fields are defined in terms of the exponential expression exp(-H), where H is...
We consider the problem of deriving the linear Boltzmann equation from the Lorentz process with hard...
Consider a dilute gas composed of a very large number of molecules moving in space according to the ...
to appear, Annals of PDEsInternational audienceWe derive the linear acoustic and Stokes-Fourier equa...
The Boltzmann equation is widely used in describing the time evolution of a rarefied gas of particle...
We investigate the far-from-equilibrium behavior of the Boltzmann equation for a gas of massless sca...
The derivation of a kinetic equation is the justification from a microscopic model describing a give...
We study the time evolution of a quantum particle in a Gaussian random environment. We show that in ...
A large system of particles is studied. Its time evolution is determined as the superposition of two...
La dérivation d'équations cinétiques consiste à obtenir, à partir d'un modèle microscopique décrivan...
. In this paper we consider a particle moving in a random distribution of obstacles. Each obstacle g...
AbstractWe consider the problem of deriving the linear Boltzmann equation from the Lorentz process w...
A measure of deviation from equilibrium of an ensemble of particles is proposed, which is physically...
We consider the problem of deriving the linear Boltzmann equation from the Lorentz process with hard...
AbstractWe study in this article the transport of particles in time-dependent random media, in the s...
Boltzmann-Gibbs random fields are defined in terms of the exponential expression exp(-H), where H is...
We consider the problem of deriving the linear Boltzmann equation from the Lorentz process with hard...
Consider a dilute gas composed of a very large number of molecules moving in space according to the ...
to appear, Annals of PDEsInternational audienceWe derive the linear acoustic and Stokes-Fourier equa...
The Boltzmann equation is widely used in describing the time evolution of a rarefied gas of particle...
We investigate the far-from-equilibrium behavior of the Boltzmann equation for a gas of massless sca...