Using the method of molecular dynamics, peculiarities of structure rearrangements in nanofiber of intermetallic compound Ni 3 Al, containing long-period antiphase boundaries are investigated in the course of high-speed uniaxial tensile loading along the direction <001>. Four principal stages of deformation (quasielastic, plastic, flow, and failure) are identified, in each of which characteristic features of structureenergy transformation peculiar for this stage are observed. It is found that the presence of planar defects in long-period nanostructure exerts a considerable effect on the variation of the onset of plastic deformation stage.
This article deals with the research of the influence of the anisotropy of the alloys properties having non-cubic symmetry for example nanofibers CuAu I during deformation at low temperatures.
Using the method of molecular dynamics, FCC Ni nanowires containing hydrogen atoms in octahedral and tetrahedral pores are investigated in the course of high-speed uniaxial tensile loading along the direction <001>. The feature of structural transformations in Ni nanowires containing hydrogen is appearance on the stage of plastic deformation globular (spherical) formations consisting of hydrogen atoms
In this work, the authors attempted to consider the influence of the geometry of the crystal lattice on the properties of nanowires, which manifest themselves in the process of uni-axial stretching. This work summarizes and systematizes the results of previous studies of the authors. The first group of samples – are typical FCC metal – Ni3Al. For these nanowires, deformation processes in directions with different packing densities of atoms <100>, <110> and <111> were investigated. The second material group studied was an alloy with the non-cubic symmetry of the element cell CuAu I. Correspondingly, this sample was examined under deformation in directions corresponding to different lengths of the sides of the unit cell, <001> and <010>. All the investigations described in this paper were carried out by molecular dynamics method on three-dimensional models using the Morse's pair potentials.
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