Code: microMegas

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(Created page with '== Overview == The microscale material model is a research code that have been developed outside and used at CAVS for modeling dislocation interactions and reactions in an elast…')
 
(Available Codes)
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** serial version [[CodeRepository:mM|mM]]
 
** serial version [[CodeRepository:mM|mM]]
 
** parallel version (openMP) [[CodeRepository:mMpar|mMpar]]
 
** parallel version (openMP) [[CodeRepository:mMpar|mMpar]]
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== References ==
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Please remember to cite the following references when publishing results obtained with microMegas:
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# S. Groh, E. B. Marin, M. F. Horstemeyer, and H. M. Zbib. Multiscale modeling of the plasticity in an aluminum single crystal. Int. J. of Plasticity, August 2009, vol. 25, pp. 1456-1473.
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# S. Groh and H. M. Zbib. Advances in Discrete Dislocations Dynamics and Multiscale Modeling, J. Eng. Mater. Technol. October 2009, vol. 131,  issue 4, 041209 (10 pages).
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Revision as of 17:23, 31 August 2010

Overview

The microscale material model is a research code that have been developed outside and used at CAVS for modeling dislocation interactions and reactions in an elastic continuum. The code is used in a hierarchical multiscale framework of the plasticity to obtained information related to the hardening of the material (see for example multiscale framework‎). Details of the discrete dislocations model can be found in the methodology‎ paper.

The discrete dislocation simulation code can be used for HCP, BCC and FCC materials.

Available Codes

  • Micromegas [1]
    • serial version mM
    • parallel version (openMP) mMpar

References

Please remember to cite the following references when publishing results obtained with microMegas:

  1. S. Groh, E. B. Marin, M. F. Horstemeyer, and H. M. Zbib. Multiscale modeling of the plasticity in an aluminum single crystal. Int. J. of Plasticity, August 2009, vol. 25, pp. 1456-1473.
  2. S. Groh and H. M. Zbib. Advances in Discrete Dislocations Dynamics and Multiscale Modeling, J. Eng. Mater. Technol. October 2009, vol. 131, issue 4, 041209 (10 pages).


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