Atoms to Autos: A Multi-scale Approach to Modeling Aluminum Deformation

Krajewski, P. E.; Hector, L. G.; Qi, Y.; Mishra, R. K.; Sachdev, A. K.; Bower, A. F.; Curtin, W. A.

doi:10.1007/s11837-011-0187-y

Krajewski, P. E.; Hector, L. G.; Qi, Y.; Mishra, R. K.; Sachdev, A. K.; Bower, A. F.; Curtin, W. A.

2011

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Abstract

A multi-scale, computational design approach for aluminum sheet alloys, which includes key inputs from the electronic, atomistic, microstructural, and continuum length scales, is reviewed within the context of room and elevated temperature forming. Specific examples, which are aimed at improving aluminum sheet materials for automobile components, include prediction of flow curves from tensile testing, forming limit diagrams, and component forming.

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Title Atoms to Autos: A Multi-scale Approach to Modeling Aluminum Deformation

Author(s) Krajewski, P. E. ; Hector, L. G. ; Qi, Y. ; Mishra, R. K. ; Sachdev, A. K. ; Bower, A. F. ; Curtin, W. A.

Published in Jom

Volume 63

Pages 24-32

Date 2011

Publisher Springer Verlag

ISSN 1047-4838

Keywords

constitutive; crystal; finite-element-method; magnesium alloys; metals; polycrystals; response; simulations; strain; stress; temperature plastic-deformation

DOI https://doi.org/10.1007/s11837-011-0187-y

Laboratories LAMMM

Record Appears in Scientific production and competences > STI - School of Engineering > IGM - Institute of Mechanical Engineering > LAMMM - Laboratory for Multiscale Mechanics Modeling
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Journal Articles
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Record creation date 2014-11-07

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