Diffusion in arrays of obstacles: Beyond homogenization: Diffusion in arrays of obstacles

Yahya Farah; Daniel Loghin; Alexandra Tzella; Jacques Vanneste

doi:10.1098/rspa.2020.0072rspa20200072

Diffusion in arrays of obstacles: Beyond homogenization: Diffusion in arrays of obstacles

Yahya Farah, Daniel Loghin, Alexandra Tzella^*, Jacques Vanneste

^*Corresponding author for this work

Mathematics

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

Abstract

We revisit the classical problem of diffusion of a scalar (or heat) released in a two-dimensional medium with an embedded periodic array of impermeable obstacles such as perforations. Homogenization theory provides a coarse-grained description of the scalar at large times and predicts that it diffuses with a certain effective diffusivity, so the concentration is approximately Gaussian. We improve on this by developing a large-deviation approximation which also captures the non-Gaussian tails of the concentration through a rate function obtained by solving a family of eigenvalue problems. We focus on cylindrical obstacles and on the dense limit, when the obstacles occupy a large area fraction and non-Gaussianity is most marked. We derive an asymptotic approximation for the rate function in this limit, valid uniformly over a wide range of distances. We use finite-element implementations to solve the eigenvalue problems yielding the rate function for arbitrary obstacle area fractions and an elliptic boundary-value problem arising in the asymptotics calculation. Comparison between numerical results and asymptotic predictions confirms the validity of the latter.

Original language	English
Article number	20200207
Journal	Proceedings of the Royal Society A: Mathematical, Physical and Engineering Sciences
Volume	476
Issue number	2244
DOIs	https://doi.org/10.1098/rspa.2020.0072rspa20200072
Publication status	Published - Dec 2020

Bibliographical note

Funding Information:
Funding. Y.F.’s research was supported by a PhD scholarship from the EPSRC. J.V.’s research was supported by EPSRC Programme Grant EP/R045046/1: Probing Multiscale Complex Multiphase Flows with Positrons for Engineering and Biomedical Applications (PI: Prof. M. Barigou, University of Birmingham). Acknowledgements. A. Tzella and D. Loghin acknowledge A. Patel for his contribution to a related MSci project.

Publisher Copyright:
© 2020 The Author(s).

Keywords

composite materials
diffusion
homogenization
large deviations
porous media

ASJC Scopus subject areas

General Mathematics
General Engineering
General Physics and Astronomy

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10.1098/rspa.2020.0072rspa20200072

Cite this

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title = "Diffusion in arrays of obstacles: Beyond homogenization: Diffusion in arrays of obstacles",

abstract = "We revisit the classical problem of diffusion of a scalar (or heat) released in a two-dimensional medium with an embedded periodic array of impermeable obstacles such as perforations. Homogenization theory provides a coarse-grained description of the scalar at large times and predicts that it diffuses with a certain effective diffusivity, so the concentration is approximately Gaussian. We improve on this by developing a large-deviation approximation which also captures the non-Gaussian tails of the concentration through a rate function obtained by solving a family of eigenvalue problems. We focus on cylindrical obstacles and on the dense limit, when the obstacles occupy a large area fraction and non-Gaussianity is most marked. We derive an asymptotic approximation for the rate function in this limit, valid uniformly over a wide range of distances. We use finite-element implementations to solve the eigenvalue problems yielding the rate function for arbitrary obstacle area fractions and an elliptic boundary-value problem arising in the asymptotics calculation. Comparison between numerical results and asymptotic predictions confirms the validity of the latter.",

keywords = "composite materials, diffusion, homogenization, large deviations, porous media",

author = "Yahya Farah and Daniel Loghin and Alexandra Tzella and Jacques Vanneste",

note = "Funding Information: Funding. Y.F.{\textquoteright}s research was supported by a PhD scholarship from the EPSRC. J.V.{\textquoteright}s research was supported by EPSRC Programme Grant EP/R045046/1: Probing Multiscale Complex Multiphase Flows with Positrons for Engineering and Biomedical Applications (PI: Prof. M. Barigou, University of Birmingham). Acknowledgements. A. Tzella and D. Loghin acknowledge A. Patel for his contribution to a related MSci project. Publisher Copyright: {\textcopyright} 2020 The Author(s).",

year = "2020",

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doi = "10.1098/rspa.2020.0072rspa20200072",

language = "English",

volume = "476",

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AU - Loghin, Daniel

AU - Tzella, Alexandra

AU - Vanneste, Jacques

N1 - Funding Information: Funding. Y.F.’s research was supported by a PhD scholarship from the EPSRC. J.V.’s research was supported by EPSRC Programme Grant EP/R045046/1: Probing Multiscale Complex Multiphase Flows with Positrons for Engineering and Biomedical Applications (PI: Prof. M. Barigou, University of Birmingham). Acknowledgements. A. Tzella and D. Loghin acknowledge A. Patel for his contribution to a related MSci project. Publisher Copyright: © 2020 The Author(s).

PY - 2020/12

Y1 - 2020/12

N2 - We revisit the classical problem of diffusion of a scalar (or heat) released in a two-dimensional medium with an embedded periodic array of impermeable obstacles such as perforations. Homogenization theory provides a coarse-grained description of the scalar at large times and predicts that it diffuses with a certain effective diffusivity, so the concentration is approximately Gaussian. We improve on this by developing a large-deviation approximation which also captures the non-Gaussian tails of the concentration through a rate function obtained by solving a family of eigenvalue problems. We focus on cylindrical obstacles and on the dense limit, when the obstacles occupy a large area fraction and non-Gaussianity is most marked. We derive an asymptotic approximation for the rate function in this limit, valid uniformly over a wide range of distances. We use finite-element implementations to solve the eigenvalue problems yielding the rate function for arbitrary obstacle area fractions and an elliptic boundary-value problem arising in the asymptotics calculation. Comparison between numerical results and asymptotic predictions confirms the validity of the latter.

AB - We revisit the classical problem of diffusion of a scalar (or heat) released in a two-dimensional medium with an embedded periodic array of impermeable obstacles such as perforations. Homogenization theory provides a coarse-grained description of the scalar at large times and predicts that it diffuses with a certain effective diffusivity, so the concentration is approximately Gaussian. We improve on this by developing a large-deviation approximation which also captures the non-Gaussian tails of the concentration through a rate function obtained by solving a family of eigenvalue problems. We focus on cylindrical obstacles and on the dense limit, when the obstacles occupy a large area fraction and non-Gaussianity is most marked. We derive an asymptotic approximation for the rate function in this limit, valid uniformly over a wide range of distances. We use finite-element implementations to solve the eigenvalue problems yielding the rate function for arbitrary obstacle area fractions and an elliptic boundary-value problem arising in the asymptotics calculation. Comparison between numerical results and asymptotic predictions confirms the validity of the latter.

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KW - large deviations

KW - porous media

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VL - 476

JO - Proceedings of the Royal Society A: Mathematical, Physical and Engineering Sciences

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ER -

Diffusion in arrays of obstacles: Beyond homogenization: Diffusion in arrays of obstacles

Abstract

Bibliographical note

Keywords

ASJC Scopus subject areas

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