Ab initio and atomistic study of generalized stacking fault energies in Mg and Mg-Y alloys

Z. Pei, L. F. Zhu, M. Friák, S. Sandlöbes, J. Von Pezold, H. W. Sheng, C. P. Race, S. Zaefferer, B. Svendsen, D. Raabe, J. Neugebauer

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Abstract

Magnesium-yttrium alloys show significantly improved room temperature ductility when compared with pure Mg. We study this interesting phenomenon theoretically at the atomic scale employing quantum-mechanical (so-called ab initio) and atomistic modeling methods. Specifically, we have calculated generalized stacking fault energies for five slip systems in both elemental magnesium (Mg) and Mg-Y alloys using (i) density functional theory and (ii) a set of embedded-atom-method (EAM) potentials. These calculations predict that the addition of yttrium results in a reduction in the unstable stacking fault energy of basal slip systems. Specifically in the case of an I2 stacking fault, the predicted reduction of the stacking fault energy due to Y atoms was verified by experimental measurements. We find a similar reduction for the stable stacking fault energy of the non-basal slip system. On the other hand, other energies along this particular γ-surface profile increase with the addition of Y. In parallel to our quantum-mechanical calculations, we have also developed a new EAM Mg-Y potential and thoroughly tested its performance. The comparison of quantum-mechanical and atomistic results indicates that the new potential is suitable for future large-scale atomistic simulations. © IOP Publishing and Deutsche Physikalische Gesellschaft.
Original languageEnglish
Article number043020
JournalNew Journal of Physics
Volume15
DOIs
Publication statusPublished - Apr 2013

Research Beacons, Institutes and Platforms

  • Dalton Nuclear Institute

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