Continuum limit and stochastic homogenization of discrete ferromagnetic thin films

Andrea Braides; Marco Cicalese; Matthias Ruf

doi:10.2140/apde.2018.11.499

Continuum limit and stochastic homogenization of discrete ferromagnetic thin films

Andrea Braides, Marco Cicalese, Matthias Ruf

Associate Professorship of Mathematical Continuum Mechanics

Research output: Contribution to journal › Article › peer-review

16 Scopus citations

Abstract

We study the discrete-to-continuum limit of ferromagnetic spin systems when the lattice spacing tends to zero. We assume that the atoms are part of a (maybe) nonperiodic lattice close to a flat set in a lower-dimensional space, typically a plate in three dimensions. Scaling the particle positions by a small parameter ε > 0, we perform a 0-convergence analysis of properly rescaled interfacial-type energies. We show that, up to subsequences, the energies converge to a surface integral defined on partitions of the flat space. In the second part of the paper we address the issue of stochastic homogenization in the case of random stationary lattices. A finer dependence of the homogenized energy on the average thickness of the random lattice is analyzed for an example of a magnetic thin system obtained by a random deposition mechanism.

Original language	English
Pages (from-to)	499-553
Number of pages	55
Journal	Analysis and PDE
Volume	11
Issue number	2
DOIs	https://doi.org/10.2140/apde.2018.11.499
State	Published - 2018

Keywords

Dimension reduction
Spin systems
Stochastic homogenization
Γ-convergence

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10.2140/apde.2018.11.499

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AU - Braides, Andrea

AU - Cicalese, Marco

AU - Ruf, Matthias

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AB - We study the discrete-to-continuum limit of ferromagnetic spin systems when the lattice spacing tends to zero. We assume that the atoms are part of a (maybe) nonperiodic lattice close to a flat set in a lower-dimensional space, typically a plate in three dimensions. Scaling the particle positions by a small parameter ε > 0, we perform a 0-convergence analysis of properly rescaled interfacial-type energies. We show that, up to subsequences, the energies converge to a surface integral defined on partitions of the flat space. In the second part of the paper we address the issue of stochastic homogenization in the case of random stationary lattices. A finer dependence of the homogenized energy on the average thickness of the random lattice is analyzed for an example of a magnetic thin system obtained by a random deposition mechanism.

KW - Dimension reduction

KW - Spin systems

KW - Stochastic homogenization

KW - Γ-convergence

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DO - 10.2140/apde.2018.11.499

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VL - 11

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JO - Analysis and PDE

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Continuum limit and stochastic homogenization of discrete ferromagnetic thin films

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