We construct classes of two-dimensional aperiodic Lorentz systems that have
infinite horizon and are 'chaotic', in the sense that they are (Poincar\'e)
recurrent, uniformly hyperbolic, ergodic, and the first-return map to any
scatterer is $K$-mixing. In the case of the Lorentz tubes (i.e., Lorentz gases
in a strip), we define general measured families of systems (\emph{ensembles})
for which the above properties occur with probability 1. In the case of the
Lorentz gases in the plane, we define families, endowed with a natural metric,
within which the set of all chaotic dynamical systems is uncountable and dense.Comment: Final version, to appear in Physica D (2011

Lenci, Marco

Troubetzkoy, Serge

Physica D Nonlinear Phenomena

English

arXiv

Final version, to appear in Physica DInternational audienceWe construct classes of two-dimensional aperiodic Lorentz systems that have infinite horizon and are 'chaotic', in the sense that they are (Poincaré) recurrent, uniformly hyperbolic, ergodic, and the first-return map to any scatterer is $K$-mixing. In the case of the Lorentz tubes (i.e., Lorentz gases in a strip), we define general measured families of systems (\emph{ensembles}) for which the above properties occur with probability 1. In the case of the Lorentz gases in the plane, we define families, endowed with a natural metric, within which the set of all chaotic dynamical systems is uncountable and dense

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Infinite-horizon Lorentz tubes and gases: recurrence and ergodic properties

Hal-Diderot

Marco Lenci

Serge Troubetzkoy

Crossref

Infinite-horizon Lorentz tubes and gases: Recurrence and ergodic properties

HAL Descartes

HAL AMU

We construct classes of two-dimensional aperiodic Lorentz systems that have infinite horizon and are 'chaotic', in the sense that they are (Poincare') recurrent, uniformly hyperbolic, ergodic, and the first-return map to any scatterer is K-mixing. In the case of the Lorentz tubes (i.e., Lorentz gases in a strip), we define general measured families of systems (ensembles) for which the above properties occur with probability 1. In the case of the Lorentz gases in the plane, we define families, endowed with a natural metric, within which the set of all chaotic dynamical systems is uncountable and dense

LENCI, MARCO

S. Troubetzkoy

Archivio istituzionale della ricerca - Alma Mater Studiorum Università di Bologna

https://hal.archives-ouvertes.fr/hal-00581551

Infinite-horizon Lorentz tubes and gases: recurrence and ergodic
  properties

Infinite-horizon Lorentz tubes and gases: recurrence and ergodic properties

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