Variable Horizon In A Peridynamic Medium

Stewart A. Silling; David J. Littlewood; Pablo Seleson

doi:10.2140/jomms.2015.10.591

Variable Horizon In A Peridynamic Medium

Stewart A. Silling
, David J. Littlewood
, Pablo Seleson

Multiscale Methods

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

117 Scopus citations

Abstract

A notion of material homogeneity is proposed for peridynamic bodies with variable horizon but constant bulk properties. A relation is derived that scales the force state according to the position-dependent horizon while keeping the bulk properties unchanged. Using this scaling relation, if the horizon depends on position, artifacts called ghost forces may arise in a body under a homogeneous deformation. These artifacts depend on the second derivative of the horizon and can be reduced by employing a modified equilibrium equation using a new quantity called the partial stress. Bodies with piecewise constant horizon can be modeled without ghost forces by using a simpler technique called a splice. As a limiting case of zero horizon, both the partial stress and splice techniques can be used to achieve local-nonlocal coupling. Computational examples, including dynamic fracture in a one-dimensional model with local- nonlocal coupling, illustrate the methods.

Original language	English
Pages (from-to)	591-612
Number of pages	22
Journal	Journal of Mechanics of Materials and Structures
Volume	10
Issue number	5
DOIs	https://doi.org/10.2140/jomms.2015.10.591
State	Published - 2015

Keywords

Elasticity
Local-nonlocal coupling
Nonlocality
Peridynamics

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10.2140/jomms.2015.10.591

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abstract = "A notion of material homogeneity is proposed for peridynamic bodies with variable horizon but constant bulk properties. A relation is derived that scales the force state according to the position-dependent horizon while keeping the bulk properties unchanged. Using this scaling relation, if the horizon depends on position, artifacts called ghost forces may arise in a body under a homogeneous deformation. These artifacts depend on the second derivative of the horizon and can be reduced by employing a modified equilibrium equation using a new quantity called the partial stress. Bodies with piecewise constant horizon can be modeled without ghost forces by using a simpler technique called a splice. As a limiting case of zero horizon, both the partial stress and splice techniques can be used to achieve local-nonlocal coupling. Computational examples, including dynamic fracture in a one-dimensional model with local- nonlocal coupling, illustrate the methods.",

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T1 - Variable Horizon In A Peridynamic Medium

AU - Silling, Stewart A.

AU - Littlewood, David J.

AU - Seleson, Pablo

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AB - A notion of material homogeneity is proposed for peridynamic bodies with variable horizon but constant bulk properties. A relation is derived that scales the force state according to the position-dependent horizon while keeping the bulk properties unchanged. Using this scaling relation, if the horizon depends on position, artifacts called ghost forces may arise in a body under a homogeneous deformation. These artifacts depend on the second derivative of the horizon and can be reduced by employing a modified equilibrium equation using a new quantity called the partial stress. Bodies with piecewise constant horizon can be modeled without ghost forces by using a simpler technique called a splice. As a limiting case of zero horizon, both the partial stress and splice techniques can be used to achieve local-nonlocal coupling. Computational examples, including dynamic fracture in a one-dimensional model with local- nonlocal coupling, illustrate the methods.

KW - Elasticity

KW - Local-nonlocal coupling

KW - Nonlocality

KW - Peridynamics

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M3 - Article

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JO - Journal of Mechanics of Materials and Structures

JF - Journal of Mechanics of Materials and Structures

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Variable Horizon In A Peridynamic Medium

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Keywords

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