Derivation of the Linear Boltzmann Equation from the Damped Quantum Lorentz Gas with a General Scatterer Configuration

Jory Griffin

doi:10.1007/s00023-022-01230-9

Derivation of the Linear Boltzmann Equation from the Damped Quantum Lorentz Gas with a General Scatterer Configuration

Jory Griffin^*

^*Corresponding author for this work

School of Mathematics

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Abstract

It is a fundamental problem in mathematical physics to derive macroscopic transport equations from microscopic models. In this paper, we derive the linear Boltzmann equation in the low-density limit of a damped quantum Lorentz gas for a large class of deterministic and random scatterer configurations. Previously this result was known only for the single-scatterer problem on the flat torus, and for uniformly random scatterer configurations where no damping is required. The damping is critical in establishing convergence—in the absence of damping the limiting behaviour depends on the exact configuration under consideration, and indeed, the linear Boltzmann equation is not expected to appear for periodic and other highly ordered configurations.

Original language	English
Article number	146
Number of pages	27
Journal	Annales Henri Poincaré
DOIs	https://doi.org/10.1007/s00023-022-01230-9
Publication status	Published - 13 Sept 2022

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Funding Information:
Research supported by EPSRC grant EP/S024948/1.

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© 2022, The Author(s).

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10.1007/s00023-022-01230-9

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title = "Derivation of the Linear Boltzmann Equation from the Damped Quantum Lorentz Gas with a General Scatterer Configuration",

abstract = "It is a fundamental problem in mathematical physics to derive macroscopic transport equations from microscopic models. In this paper, we derive the linear Boltzmann equation in the low-density limit of a damped quantum Lorentz gas for a large class of deterministic and random scatterer configurations. Previously this result was known only for the single-scatterer problem on the flat torus, and for uniformly random scatterer configurations where no damping is required. The damping is critical in establishing convergence—in the absence of damping the limiting behaviour depends on the exact configuration under consideration, and indeed, the linear Boltzmann equation is not expected to appear for periodic and other highly ordered configurations.",

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N2 - It is a fundamental problem in mathematical physics to derive macroscopic transport equations from microscopic models. In this paper, we derive the linear Boltzmann equation in the low-density limit of a damped quantum Lorentz gas for a large class of deterministic and random scatterer configurations. Previously this result was known only for the single-scatterer problem on the flat torus, and for uniformly random scatterer configurations where no damping is required. The damping is critical in establishing convergence—in the absence of damping the limiting behaviour depends on the exact configuration under consideration, and indeed, the linear Boltzmann equation is not expected to appear for periodic and other highly ordered configurations.

AB - It is a fundamental problem in mathematical physics to derive macroscopic transport equations from microscopic models. In this paper, we derive the linear Boltzmann equation in the low-density limit of a damped quantum Lorentz gas for a large class of deterministic and random scatterer configurations. Previously this result was known only for the single-scatterer problem on the flat torus, and for uniformly random scatterer configurations where no damping is required. The damping is critical in establishing convergence—in the absence of damping the limiting behaviour depends on the exact configuration under consideration, and indeed, the linear Boltzmann equation is not expected to appear for periodic and other highly ordered configurations.

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JO - Annales Henri Poincaré

JF - Annales Henri Poincaré

M1 - 146

ER -

Derivation of the Linear Boltzmann Equation from the Damped Quantum Lorentz Gas with a General Scatterer Configuration

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