Influence of the Crystallographic and the Morphological Texture on the Elastic Properties of Fcc Crystal Aggregates

K. Jöchen; Thomas Böhlke; F. Fritzen

doi:10.4028/www.scientific.net/SSP.160.83

Paper Titles

Development of a 3D Crystal Plasticity Model that Tracks Dislocation Density Evolution
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Texture Analysis with MTEX – Free and Open Source Software Toolbox
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Structure Stability and Magnetic Properties of Ni₂XGa (X = Mn, Fe, Co) Ferromagnetic Shape Memory Alloys by DFT Approach
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Magnetic Quantitative Texture Analysis Using Isotropic Thermal Neutron Beams
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Influence of the Crystallographic and the Morphological Texture on the Elastic Properties of Fcc Crystal Aggregates
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On the Combination of Self-Consistent and Geometric Mean Elements for the Calculation of the Elastic Properties of Textured Multi-Phase Samples
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Frequencies of Tilt and Twist Boundaries among Random Grain Boundaries
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Texture/Stress Characteristics of Microstructure Used in Interpreting Deformation Effects of Ti Subjected to ECAP Process
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Stress, Texture and Phase Transformation in Titanium Thin Films
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Influence of the Crystallographic and the Morphological Texture on the Elastic Properties of Fcc Crystal Aggregates

Abstract:

In this contribution, the prediction of the self-consistent homogenization method with regard to the effective material response of cubic crystal aggregates is analyzed and compared to results from full field simulations. The influence of the crystalline orientation distribution but also the effect of the grain shape on the macroscopic elastic response of sheet metals is especially emphasized.

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Periodical:

Solid State Phenomena (Volume 160)

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83-86

DOI:

https://doi.org/10.4028/www.scientific.net/SSP.160.83

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Online since:

February 2010

Authors:

K. Jöchen, Thomas Böhlke, F. Fritzen

Keywords:

Crystallographic Texture, Morphological Texture, Self-Consistent Homogenization

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References

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