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A low-temperature prismatic slip instability in Mg understood using machine learning potentials

Xin Liu, Masoud Rahbar Niazi, Tao Liu, Binglun Yin, W.A. Curtin

2022Acta Materialia16 citationsDOIOpen Access PDF

Abstract

Prismatic slip in magnesium at temperatures T≲150 K occurs at ∼ 100 MPa independent of temperature, and jerky flow due to large prismatic dislocation glide distances is observed; this athermal regime is not understood. In contrast, the behavior at T≳150 K is understood to be governed by a thermally-activated double-cross-slip of the stable basal screw dislocation through an unstable or weakly metastable prism screw configuration and back to the basal screw. Here, a range of neural network potentials (NNPs) that are very similar for many properties of Mg including the basal-prism-basal cross-slip path and process, are shown to have an instability in prism slip at a potential-dependent critical stress. One NNP, NNP-77, has a critical instability stress in good agreement with experiments and also has basal-prism-basal transition path energies in very good agreement with DFT results, making it an excellent potential for understanding Mg prism slip. Full 3d simulations of the expansion of a prismatic loop using NNP-77 then also show a transition from cross-slip onto the basal plane at low stresses to prismatic loop expansion with no cross-slip at higher stresses, consistent with in-situ TEM observations. These results reveal (i) the origin and prediction of the observed unstable low-T prismatic slip in Mg and (ii) the critical use of machine-learning potentials to guide discovery and understanding of new important metallurgical behavior.

Topics & Concepts

Slip (aerodynamics)Materials scienceInstabilityMetastabilitySlip line fieldBasal planeCrystallographyDislocationComposite materialMechanicsThermodynamicsPhysicsChemistryQuantum mechanicsMagnesium Alloys: Properties and ApplicationsMetal and Thin Film MechanicsMicrostructure and mechanical properties
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