Kinetic Description of a Rayleigh Gas with Annihilation

Nota, Alessia; Winter, Raphael; Lods, Bertrand

doi:10.1007/s10955-019-02348-7

Cited by 3 publications

(2 citation statements)

References 21 publications

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“…The derivation of (4) is given in [MST18] for finite, fixed times without any error estimates. For variants and further details see also [Sto17,MS18] and for a related model [NWL19]. Various scaling limits can be considered for systems with long-range potential [NVW21].…”

Section: Macroscopic Descriptionmentioning

confidence: 99%

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The derivation of the linear Boltzmann equation from a Rayleigh gas particle model

Matthies

Stone²,

Theil

2018

Kinetic &Amp; Related Models

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A linear Boltzmann equation is derived in the Boltzmann-Grad scaling for the deterministic dynamics of many interacting particles with random initial data. We study a Rayleigh gas where a tagged particle is undergoing hard-sphere collisions with background particles, which do not interact among each other. In the Boltzmann-Grad scaling, we derive the validity of a linear Boltzmann equation for arbitrary long times under moderate assumptions on higher moments of the initial distributions of the tagged particle and the possibly nonequilibrium distribution of the background. The convergence of the empiric dynamics to the Boltzmann dynamics is shown using Kolmogorov equations for associated probability measures on collision histories.Proposition 2.1. For N ∈ N and T > 0 fixed these dynamics are well defined up to time T for all initial configurations apart from a set of measure zero. 3 εν

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Section: Macroscopic Descriptionmentioning

confidence: 99%

“…Also in [ET17] they derive the linear Boltzmann equation (1.4) from a long range particle evolution. For variants and further details see also [Sto17,MS18] and for a related model [NWL19]. Various scaling limits can be considered for systems with long-range potential [NVW21].…”

Section: Introductionmentioning

confidence: 99%

The derivation of the linear Boltzmann equation from a Rayleigh gas particle model

Matthies

Stone²,

Theil

2018

Kinetic &Amp; Related Models

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A Kac Model for Kinetic Annihilation

2020

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In this paper we consider the stochastic dynamics of a finite system of particles in a finite volume (Kac-like particle system) which annihilate with probability α ∈ (0, 1) or collide elastically with probability 1 − α. We first establish the well-posedness of the particle system which exhibits no conserved quantities. We rigorously prove that, in some thermodynamic limit, a suitable hierarchy of kinetic equations is recovered for which tensorized solution to the homogenous Boltzmann with annihilation is a solution. For bounded collision kernels, this shows in particular that propagation of chaos holds true. Furthermore, we make conjectures about the limit behaviour of the particle system when hard-sphere interactions are taken into account.

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