Dislocation Density Based Crystal Plasticity Finite Element Model of Polycrystals with Grain Boundary Effect

  1. Mei Li,
  2. Carelyn Campbell,
  3. Katsuyo Thornton,
  4. Elizabeth Holm and
  5. Peter Gumbsch
  1. Zhe Leng1,
  2. Alankar Alankar2,
  3. David P. Field1,
  4. Nathalie Allain-Bonasso3 and
  5. Francis Wagner3

Published Online: 12 JUL 2013

DOI: 10.1002/9781118767061.ch44

2 World Congress on Integrated Computational Materials Engineering

2 World Congress on Integrated Computational Materials Engineering

How to Cite

Leng, Z., Alankar, A., Field, D. P., Allain-Bonasso, N. and Wagner, F. (2013) Dislocation Density Based Crystal Plasticity Finite Element Model of Polycrystals with Grain Boundary Effect, in 2 World Congress on Integrated Computational Materials Engineering (eds M. Li, C. Campbell, K. Thornton, E. Holm and P. Gumbsch), John Wiley & Sons, Inc., Hoboken, NJ, USA. doi: 10.1002/9781118767061.ch44

Author Information

  1. 1

    School of Mechanical and Materials Engineering, Washington State University

  2. 2

    Los Alamos National Laboratory, Los Alamos 87544, NM

  3. 3

    LEM3, Univ. of Metz, Metz, France

Publication History

  1. Published Online: 12 JUL 2013
  2. Published Print: 21 JUN 2013

ISBN Information

Print ISBN: 9781118766897

Online ISBN: 9781118767061

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Keywords:

  • Gráin boundary;
  • Geometrically necessary dislocation;
  • Crystal plasticity;
  • Finite element simulation

Summary

This chapter contains sections titled:

  • Introduction

  • Crystal Kinematics

  • Constitutive Law

  • Dislocation Density Based Framework

  • Grain Boundary Effect

  • Uniaxial Tensile Test

  • Simulation Results and Concusions