Towards scaling laws in random polycrystals

Shivakumar I. Ranganathan; Martin Ostoja-Starzewski

doi:10.1016/j.ijengsci.2009.05.003

Towards scaling laws in random polycrystals

Shivakumar I. Ranganathan, Martin Ostoja-Starzewski

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

Abstract

We propose a methodology to set up unifying scaling laws describing the response of multifarious random polycrystals. The methodology employed falls in the realm of stochastic micro-mechanics and is consistent with the Hill condition. Within this framework, we introduce the concept of a scaling function that describes "finite size scaling" of both elastic and inelastic crystalline aggregates. While the finite size is represented by the mesoscale, the scaling function depends on an appropriate measure quantifying the single crystal anisotropy. Based on the scaling function, we construct a material scaling diagram, from which one can assess the approach to a representative volume element (RVE) for many different polycrystals. We demonstrate these concepts on the scaling of the fourth-rank elasticity and the second-rank thermal conductivity tensors.

Original language	English (US)
Pages (from-to)	1322-1330
Number of pages	9
Journal	International Journal of Engineering Science
Volume	47
Issue number	11-12
DOIs	https://doi.org/10.1016/j.ijengsci.2009.05.003
State	Published - Nov 2009

Keywords

Effective response
Homogenization
Mesoscale
Random media
Scale effect
Scaling

ASJC Scopus subject areas

General Materials Science
Mechanics of Materials
General Engineering
Mechanical Engineering

Online availability

10.1016/j.ijengsci.2009.05.003

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title = "Towards scaling laws in random polycrystals",

abstract = "We propose a methodology to set up unifying scaling laws describing the response of multifarious random polycrystals. The methodology employed falls in the realm of stochastic micro-mechanics and is consistent with the Hill condition. Within this framework, we introduce the concept of a scaling function that describes {"}finite size scaling{"} of both elastic and inelastic crystalline aggregates. While the finite size is represented by the mesoscale, the scaling function depends on an appropriate measure quantifying the single crystal anisotropy. Based on the scaling function, we construct a material scaling diagram, from which one can assess the approach to a representative volume element (RVE) for many different polycrystals. We demonstrate these concepts on the scaling of the fourth-rank elasticity and the second-rank thermal conductivity tensors.",

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AU - Ranganathan, Shivakumar I.

AU - Ostoja-Starzewski, Martin

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N2 - We propose a methodology to set up unifying scaling laws describing the response of multifarious random polycrystals. The methodology employed falls in the realm of stochastic micro-mechanics and is consistent with the Hill condition. Within this framework, we introduce the concept of a scaling function that describes "finite size scaling" of both elastic and inelastic crystalline aggregates. While the finite size is represented by the mesoscale, the scaling function depends on an appropriate measure quantifying the single crystal anisotropy. Based on the scaling function, we construct a material scaling diagram, from which one can assess the approach to a representative volume element (RVE) for many different polycrystals. We demonstrate these concepts on the scaling of the fourth-rank elasticity and the second-rank thermal conductivity tensors.

AB - We propose a methodology to set up unifying scaling laws describing the response of multifarious random polycrystals. The methodology employed falls in the realm of stochastic micro-mechanics and is consistent with the Hill condition. Within this framework, we introduce the concept of a scaling function that describes "finite size scaling" of both elastic and inelastic crystalline aggregates. While the finite size is represented by the mesoscale, the scaling function depends on an appropriate measure quantifying the single crystal anisotropy. Based on the scaling function, we construct a material scaling diagram, from which one can assess the approach to a representative volume element (RVE) for many different polycrystals. We demonstrate these concepts on the scaling of the fourth-rank elasticity and the second-rank thermal conductivity tensors.

KW - Effective response

KW - Homogenization

KW - Mesoscale

KW - Random media

KW - Scale effect

KW - Scaling

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Towards scaling laws in random polycrystals

Abstract

Keywords

ASJC Scopus subject areas

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