Numerically robust spectral methods for crystal plasticity simulations of heterogeneous materials

Pratheek Shanthraj; Philip Eisenlohr; Martin Diehl; Franz Roters

doi:10.1016/j.ijplas.2014.02.006

Numerically robust spectral methods for crystal plasticity simulations of heterogeneous materials

Pratheek Shanthraj, Philip Eisenlohr, Martin Diehl, Franz Roters

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

Abstract

Efficient spectral methods are developed to predict the micromechanical behaviour of plastically deforming heterogeneous materials. The direct and mixed variational conditions for mechanical equilibrium and strain compatibility are formulated in a framework that couples them to a general class of non-linear solution methods. Locally evolving micromechanical fields in a sheared polycrystalline material governed by a phenomenological crystal plasticity constitutive law are used to validate the methods, and their performance at varying material heterogeneities is benchmarked. The results indicate that the solution method has a dominant influence on performance and stability at large material heterogeneities, and significant improvements over the conventional fixed-point approach are obtained when higher-order solution methods are employed. Optimal solution strategies are devised based on this and applied to an idealised dual-phase polycrystalline aggregate.

Original language	English
Pages (from-to)	31-45
Number of pages	15
Journal	International Journal of Plasticity
Volume	66
Early online date	23 May 2014
DOIs	https://doi.org/10.1016/j.ijplas.2014.02.006
Publication status	Published - 1 Mar 2015

Keywords

Spectral method
Numerical algorithms
Crystal plasticity
periodic volume element
Voids and inclusions

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10.1016/j.ijplas.2014.02.006

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title = "Numerically robust spectral methods for crystal plasticity simulations of heterogeneous materials",

abstract = "Efficient spectral methods are developed to predict the micromechanical behaviour of plastically deforming heterogeneous materials. The direct and mixed variational conditions for mechanical equilibrium and strain compatibility are formulated in a framework that couples them to a general class of non-linear solution methods. Locally evolving micromechanical fields in a sheared polycrystalline material governed by a phenomenological crystal plasticity constitutive law are used to validate the methods, and their performance at varying material heterogeneities is benchmarked. The results indicate that the solution method has a dominant influence on performance and stability at large material heterogeneities, and significant improvements over the conventional fixed-point approach are obtained when higher-order solution methods are employed. Optimal solution strategies are devised based on this and applied to an idealised dual-phase polycrystalline aggregate.",

keywords = "Spectral method, Numerical algorithms, Crystal plasticity, periodic volume element, Voids and inclusions",

author = "Pratheek Shanthraj and Philip Eisenlohr and Martin Diehl and Franz Roters",

year = "2015",

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doi = "10.1016/j.ijplas.2014.02.006",

language = "English",

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journal = "International Journal of Plasticity",

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TY - JOUR

T1 - Numerically robust spectral methods for crystal plasticity simulations of heterogeneous materials

AU - Shanthraj, Pratheek

AU - Eisenlohr, Philip

AU - Diehl, Martin

AU - Roters, Franz

PY - 2015/3/1

Y1 - 2015/3/1

N2 - Efficient spectral methods are developed to predict the micromechanical behaviour of plastically deforming heterogeneous materials. The direct and mixed variational conditions for mechanical equilibrium and strain compatibility are formulated in a framework that couples them to a general class of non-linear solution methods. Locally evolving micromechanical fields in a sheared polycrystalline material governed by a phenomenological crystal plasticity constitutive law are used to validate the methods, and their performance at varying material heterogeneities is benchmarked. The results indicate that the solution method has a dominant influence on performance and stability at large material heterogeneities, and significant improvements over the conventional fixed-point approach are obtained when higher-order solution methods are employed. Optimal solution strategies are devised based on this and applied to an idealised dual-phase polycrystalline aggregate.

AB - Efficient spectral methods are developed to predict the micromechanical behaviour of plastically deforming heterogeneous materials. The direct and mixed variational conditions for mechanical equilibrium and strain compatibility are formulated in a framework that couples them to a general class of non-linear solution methods. Locally evolving micromechanical fields in a sheared polycrystalline material governed by a phenomenological crystal plasticity constitutive law are used to validate the methods, and their performance at varying material heterogeneities is benchmarked. The results indicate that the solution method has a dominant influence on performance and stability at large material heterogeneities, and significant improvements over the conventional fixed-point approach are obtained when higher-order solution methods are employed. Optimal solution strategies are devised based on this and applied to an idealised dual-phase polycrystalline aggregate.

KW - Spectral method

KW - Numerical algorithms

KW - Crystal plasticity

KW - periodic volume element

KW - Voids and inclusions

U2 - 10.1016/j.ijplas.2014.02.006

DO - 10.1016/j.ijplas.2014.02.006

M3 - Article

SN - 0749-6419

VL - 66

SP - 31

EP - 45

JO - International Journal of Plasticity

JF - International Journal of Plasticity

ER -

Numerically robust spectral methods for crystal plasticity simulations of heterogeneous materials

Abstract

Keywords

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