Effective Dynamic Properties of a Row of Elastic Inclusions: The Case of Scalar Shear Waves

Jean Jacques Marigo; Agnès Maurel; Kim Pham; Amine Sbitti

doi:10.1007/s10659-017-9627-4

Effective Dynamic Properties of a Row of Elastic Inclusions: The Case of Scalar Shear Waves

Jean Jacques Marigo, Agnès Maurel, Kim Pham, Amine Sbitti

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

Abstract

We present the homogenization of a periodic array of elastic inclusions embedded in an elastic matrix. We consider shear elastic waves with a typical wavelength 1 / k much larger than the array spacing h and thickness e. Owing to the small parameter η= kh, with e/ h= O(1) , a matched asymptotic expansion technique is applied to the wave equation in the time domain. The homogenized problem involves an equivalent interface associated to jump conditions of the Ventcels type. Up to the accuracy of the model in O(η²) , different jump conditions are possible, which correspond to enlarged versions of the interface; these jump conditions are parametrized by the thickness a of the homogenized interface. We inspect the influence of a (i) on the equation of energy conservation in the homogenized problem and (ii) on the error of the model for a simple scattering problem. We show that restoring the thickness of the real array, a= e, is the optimal configuration regarding both aspects.

Original language	English
Pages (from-to)	265-289
Number of pages	25
Journal	Journal of Elasticity
Volume	128
Issue number	2
DOIs	https://doi.org/10.1007/s10659-017-9627-4
Publication status	Published - 1 Aug 2017

Keywords

Interface homogenization
Matched asymptotic expansion
Shear waves

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10.1007/s10659-017-9627-4

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title = "Effective Dynamic Properties of a Row of Elastic Inclusions: The Case of Scalar Shear Waves",

abstract = "We present the homogenization of a periodic array of elastic inclusions embedded in an elastic matrix. We consider shear elastic waves with a typical wavelength 1 / k much larger than the array spacing h and thickness e. Owing to the small parameter η= kh, with e/ h= O(1) , a matched asymptotic expansion technique is applied to the wave equation in the time domain. The homogenized problem involves an equivalent interface associated to jump conditions of the Ventcels type. Up to the accuracy of the model in O(η2) , different jump conditions are possible, which correspond to enlarged versions of the interface; these jump conditions are parametrized by the thickness a of the homogenized interface. We inspect the influence of a (i) on the equation of energy conservation in the homogenized problem and (ii) on the error of the model for a simple scattering problem. We show that restoring the thickness of the real array, a= e, is the optimal configuration regarding both aspects.",

keywords = "Interface homogenization, Matched asymptotic expansion, Shear waves",

author = "Marigo, \{Jean Jacques\} and Agn{\`e}s Maurel and Kim Pham and Amine Sbitti",

note = "Publisher Copyright: {\textcopyright} 2017, Springer Science+Business Media Dordrecht.",

year = "2017",

month = aug,

day = "1",

doi = "10.1007/s10659-017-9627-4",

language = "English",

volume = "128",

pages = "265--289",

journal = "Journal of Elasticity",

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TY - JOUR

T1 - Effective Dynamic Properties of a Row of Elastic Inclusions

T2 - The Case of Scalar Shear Waves

AU - Marigo, Jean Jacques

AU - Maurel, Agnès

AU - Pham, Kim

AU - Sbitti, Amine

PY - 2017/8/1

Y1 - 2017/8/1

N2 - We present the homogenization of a periodic array of elastic inclusions embedded in an elastic matrix. We consider shear elastic waves with a typical wavelength 1 / k much larger than the array spacing h and thickness e. Owing to the small parameter η= kh, with e/ h= O(1) , a matched asymptotic expansion technique is applied to the wave equation in the time domain. The homogenized problem involves an equivalent interface associated to jump conditions of the Ventcels type. Up to the accuracy of the model in O(η2) , different jump conditions are possible, which correspond to enlarged versions of the interface; these jump conditions are parametrized by the thickness a of the homogenized interface. We inspect the influence of a (i) on the equation of energy conservation in the homogenized problem and (ii) on the error of the model for a simple scattering problem. We show that restoring the thickness of the real array, a= e, is the optimal configuration regarding both aspects.

AB - We present the homogenization of a periodic array of elastic inclusions embedded in an elastic matrix. We consider shear elastic waves with a typical wavelength 1 / k much larger than the array spacing h and thickness e. Owing to the small parameter η= kh, with e/ h= O(1) , a matched asymptotic expansion technique is applied to the wave equation in the time domain. The homogenized problem involves an equivalent interface associated to jump conditions of the Ventcels type. Up to the accuracy of the model in O(η2) , different jump conditions are possible, which correspond to enlarged versions of the interface; these jump conditions are parametrized by the thickness a of the homogenized interface. We inspect the influence of a (i) on the equation of energy conservation in the homogenized problem and (ii) on the error of the model for a simple scattering problem. We show that restoring the thickness of the real array, a= e, is the optimal configuration regarding both aspects.

KW - Interface homogenization

KW - Matched asymptotic expansion

KW - Shear waves

U2 - 10.1007/s10659-017-9627-4

DO - 10.1007/s10659-017-9627-4

M3 - Article

AN - SCOPUS:85014101572

SN - 0374-3535

VL - 128

SP - 265

EP - 289

JO - Journal of Elasticity

JF - Journal of Elasticity

IS - 2

ER -

Effective Dynamic Properties of a Row of Elastic Inclusions: The Case of Scalar Shear Waves

Abstract

Keywords

UN SDGs

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