Article ID | Journal | Published Year | Pages | File Type |
---|---|---|---|---|
7965855 | Journal of Nuclear Materials | 2015 | 13 Pages |
Abstract
Molecular dynamics simulation is used to characterize the deformation behavior of polycrystalline Zr. The predictions of two different potentials, an embedded atom method potential and a charge optimized many body potential are compared. The experimentally observed prismatic dislocations, pyramidal dislocations and twinning behaviors are produced in the simulations of [112¯0] and [0 0 0 1] textured structures and in fully 3D structure simulations. The relationship between the generalized stacking fault energy and the mechanical properties is discussed. In particular we find that the different shapes of the generalized stacking-fault energy curve for the two different interatomic descriptions of Zr have a significant effect on the deformation mechanisms. The deformation behavior of Zr is compared with analogous simulations of deformation of polycrystalline Mg.
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Authors
Zizhe (è¦åå²), Mark J. Noordhoek, Aleksandr Chernatynskiy, Susan B. Sinnott, Simon R. Phillpot,