Brittle and ductile crack-tip behavior in magnesium

Brittle and ductile crack-tip behavior in magnesium

The competition between dislocation emission and cleavage at a crack tip plays an important role in governing the intrinsic fracture behavior of crystalline materials. This competition is not well understood in magnesium, which has many different combinations of cleavage planes and dislocation slip...

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Bibliographic Details
Published in:Acta materialia Vol. 88; pp. 1 - 12
Main Authors: Wu, Z., Curtin, W.A.
Format: Journal Article
Language:English
Published: Elsevier Ltd 15-04-2015
Subjects:
Cleavage
Competition
Cracks
Dislocations
Fracture
Fracture mechanics
Magnesium
Molecular dynamics simulations
Planes
Simulation
Slip
Cracks
Fracture
Magnesium
Molecular dynamics simulations
Dislocations
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Summary:The competition between dislocation emission and cleavage at a crack tip plays an important role in governing the intrinsic fracture behavior of crystalline materials. This competition is not well understood in magnesium, which has many different combinations of cleavage planes and dislocation slip systems. Here, using both anisotropic linear elastic fracture mechanics theory and atomistic simulations, the emission/cleavage competition in magnesium is evaluated for a comprehensive set of crack orientations and crack tip geometries under mode I crack tip stress intensity loading at T=0K. Both theory and simulation show that cleavage is favored in most crack orientations, including basal plane cracks, tensile twin and basal-prismatic plane interface cracks. Initial slight crack tip blunting does not significantly change the behavior. These results suggest that magnesium has extremely low intrinsic fracture toughness, consistent with observations of many different cleavage-like planes in low-temperature fracture experiments. Based on T=0K properties, obtaining a more-ductile material via crack tip dislocation emission on the pyramidal and basal slip systems would require substantial and moderate reductions of the unstable stacking fault energy (∼50% and ∼20%, respectively) to be achieved at finite temperatures and/or via alloying.
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ISSN:1359-6454
1873-2453
DOI:10.1016/j.actamat.2015.01.023