The strengthening mechanisms in magnesium alloys are strongly related to the complex intermetallic precipitates that spread all over the microstructure. In particular, the hard and brittle Laves phases [1] commonly observed in such alloys exhibit a complex atoms stacking with largely unknown plasticity mechanisms [2].

We propose here a numerical atomistic approach at the cross-road of experiments and ab initio simulations, to shed light on the responsible mechanisms for the plasticity in hexagonal Mg₂Ca (C14) Laves phases. Elastic and plastic properties of bulk Laves phase are investigated by both first principle and classical atomistic simulations. Molecular dynamics/statics simulations with a robust MEAM interatomic potential are performed to study the propagation of dislocations, by a combination of nudge-elastic-band (NEB) methods and nano-mechanical tests. In particular, the cross-slip to pyramidal slip planes, the propagation of dislocations in the basal plane by the so called synchroshear mechanism [3,4] and the influence of temperature on slip systems activation, are investigated at the atomic scale. All these results are finally correlated and discussed by considering experimental findings, especially from micro-pillar compression tests. Our goal is to improve the understanding of the largely unknown plasticity of Laves phases.

References:
[1] - F. Laves and H. Witte, Metallwirtsch. Metallwiss. Metalltech. 15, 840 (1936).
[2] - M.F. Chisholm, et al., Science 307, 701 (2005)
[3] - P.M. Hazzledine et al., MRS Proceedings 288, 591 (1992)
[4] - P.M. Hazzledine and P. Pirouz, Scripta metallurgica et materialia 28, 1277 (1993).