On the Boltzmann-Grad Limit for the Two Dimensional Periodic Lorentz Gas

The two-dimensional, periodic Lorentz gas, is the dynamical system corresponding with the free motion of a point particle in a planar system of fixed circular obstacles centered at the vertices of a square lattice in the Euclidean plane. Assuming elastic collisions between the particle and the obsta...

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Bibliographic Details
Published in:Journal of statistical physics 2010, Vol.141 (2), p.264-317
Main Authors: Caglioti, Emanuele, Golse, François
Format: Article
Language:English
Subjects:
Analysis of PDEs
Differential Geometry
Mathematical and Computational Physics
Mathematical Physics
Mathematics
Physical Chemistry
Physics
Physics and Astronomy
Quantum Physics
Statistical Physics and Dynamical Systems
Theoretical
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Summary:The two-dimensional, periodic Lorentz gas, is the dynamical system corresponding with the free motion of a point particle in a planar system of fixed circular obstacles centered at the vertices of a square lattice in the Euclidean plane. Assuming elastic collisions between the particle and the obstacles, this dynamical system is studied in the Boltzmann-Grad limit, assuming that the obstacle radius r and the reciprocal mean free path are asymptotically equivalent small quantities, and that the particle’s distribution function is slowly varying in the space variable. In this limit, the periodic Lorentz gas cannot be described by a linear Boltzmann equation (see Golse in Ann. Fac. Sci. Toulouse 17:735–749, 2008 ), but involves an integro-differential equation conjectured in Caglioti and Golse (C. R. Acad. Sci. Sér. I Math. 346:477–482, 2008 ) and proved in Marklof and Strömbergsson (preprint arXiv:0801.0612 ), set on a phase-space larger than the usual single-particle phase-space. The main purpose of the present paper is to study the dynamical properties of this integro-differential equation: identifying its equilibrium states, proving a H Theorem and discussing the speed of approach to equilibrium in the long time limit. In the first part of the paper, we derive the explicit formula for a transition probability appearing in that equation following the method sketched in Caglioti and Golse (C. R. Acad. Sci. Sér. I Math. 346:477–482, 2008 ).
ISSN:0022-4715
1572-9613
DOI:10.1007/s10955-010-0046-1