Improved geometric and recollision estimates for the invariance principle of the random Lorentz gas

Karsten Matthies; Raphael Winter

Improved geometric and recollision estimates for the invariance principle of the random Lorentz gas

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Abstract

By improving geometric recollision estimates for a random Lorentz gas, we extend the timescale $T(r)$ of the invariance principle for a Lorentz gas with particle size $r$ obtained by Lutsko and T\'oth (2020) from $\lim_{r \rightarrow 0} T(r) r^{2} |\log(r)|^2 =0$ to $\lim_{r \rightarrow 0} T(r) r^{2} |\log(r)| =0$. We show that this is the maximal reachable timescale with the coupling of stochastic processes introduced in the original result. In our improved geometric estimates we make use of the convexity of scatterers to obtain better dispersive estimates for the associated billiard map. We provide additional estimates on the exit distribution of simple recollisions.

Original language	English
Journal	Nonlinearity
Publication status	Acceptance date - 2 Feb 2026

Funding

This work was partially supported through The Leverhulme Trust research project grant RPG-2020-107. The authors would like to thank the Isaac Newton Institute for Mathematical Sciences, Cambridge, for support and hospitality during the programme \emph{Frontiers in kinetic theory} where this work was initiated.

Keywords

0F17, 60K35, 60K37, 60K40, 82C22, 82C31, 82C40, 82C41

Embargoed Document

MatthiesWinterLorentzaccepted
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Embargo ends: 31/12/99
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Derivation of kinetic equation: From Newton to Boltzmann via trees
Matthies, K. (PI)
The Leverhulme Trust
1/10/20 → 31/03/24
Project: UK charity

Cite this

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title = "Improved geometric and recollision estimates for the invariance principle of the random Lorentz gas",

abstract = "By improving geometric recollision estimates for a random Lorentz gas, we extend the timescale \$T(r)\$ of the invariance principle for a Lorentz gas with particle size \$r\$ obtained by Lutsko and T\textbackslash{}'oth (2020) from \$\textbackslash{}lim\_\{r \textbackslash{}rightarrow 0\} T(r) r\textasciicircum{}\{2\} |\textbackslash{}log(r)|\textasciicircum{}2 =0\$ to \$\textbackslash{}lim\_\{r \textbackslash{}rightarrow 0\} T(r) r\textasciicircum{}\{2\} |\textbackslash{}log(r)| =0\$. We show that this is the maximal reachable timescale with the coupling of stochastic processes introduced in the original result. In our improved geometric estimates we make use of the convexity of scatterers to obtain better dispersive estimates for the associated billiard map. We provide additional estimates on the exit distribution of simple recollisions.",

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author = "Karsten Matthies and Raphael Winter",

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day = "2",

language = "English",

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issn = "0951-7715",

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TY - JOUR

T1 - Improved geometric and recollision estimates for the invariance principle of the random Lorentz gas

AU - Matthies, Karsten

AU - Winter, Raphael

PY - 2026/2/2

Y1 - 2026/2/2

N2 - By improving geometric recollision estimates for a random Lorentz gas, we extend the timescale $T(r)$ of the invariance principle for a Lorentz gas with particle size $r$ obtained by Lutsko and T\'oth (2020) from $\lim_{r \rightarrow 0} T(r) r^{2} |\log(r)|^2 =0$ to $\lim_{r \rightarrow 0} T(r) r^{2} |\log(r)| =0$. We show that this is the maximal reachable timescale with the coupling of stochastic processes introduced in the original result. In our improved geometric estimates we make use of the convexity of scatterers to obtain better dispersive estimates for the associated billiard map. We provide additional estimates on the exit distribution of simple recollisions.

AB - By improving geometric recollision estimates for a random Lorentz gas, we extend the timescale $T(r)$ of the invariance principle for a Lorentz gas with particle size $r$ obtained by Lutsko and T\'oth (2020) from $\lim_{r \rightarrow 0} T(r) r^{2} |\log(r)|^2 =0$ to $\lim_{r \rightarrow 0} T(r) r^{2} |\log(r)| =0$. We show that this is the maximal reachable timescale with the coupling of stochastic processes introduced in the original result. In our improved geometric estimates we make use of the convexity of scatterers to obtain better dispersive estimates for the associated billiard map. We provide additional estimates on the exit distribution of simple recollisions.

KW - 0F17, 60K35, 60K37, 60K40, 82C22, 82C31, 82C40, 82C41

M3 - Article

SN - 0951-7715

JO - Nonlinearity

JF - Nonlinearity

ER -

Improved geometric and recollision estimates for the invariance principle of the random Lorentz gas

Abstract

Funding

Keywords

Embargoed Document

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Derivation of kinetic equation: From Newton to Boltzmann via trees

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