• Title of article

    Atomistic simulations of diffusional creep in a nanocrystalline body-centered cubic material Original Research Article

  • Author/Authors

    Paul C. Millett، نويسنده , , Tapan Desai، نويسنده , , Vesselin Yamakov، نويسنده , , Dieter Wolf، نويسنده ,

  • Issue Information
    دوهفته نامه با شماره پیاپی سال 2008
  • Pages
    11
  • From page
    3688
  • To page
    3698
  • Abstract
    Molecular dynamics (MD) simulations are used to study diffusion-accommodated creep deformation in nanocrystalline molybdenum, a body-centered cubic metal. In our simulations, the microstructures are subjected to constant-stress loading at levels below the dislocation nucleation threshold and at high temperatures (i.e., T > 0.75Tmelt), thereby ensuring that the overall deformation is indeed attributable to atomic self-diffusion. The initial microstructures were designed to consist of hexagonally shaped columnar grains bounded by high-energy asymmetric tilt grain boundaries (GBs). Remarkably the creep rates, which exhibit a double-exponential dependence on temperature and a double power-law dependence on grain size, indicate that both GB diffusion in the form of Coble creep and lattice diffusion in the form of Nabarro–Herring creep contribute to the overall deformation. For the first time in an MD simulation, we observe the formation and emission of vacancies from high-angle GBs into the grain interiors, thus enabling bulk diffusion.
  • Keywords
    Grain boundary diffusion , Nanocrystalline materials , molecular dynamics , Creep , Bulk diffusion
  • Journal title
    ACTA Materialia
  • Serial Year
    2008
  • Journal title
    ACTA Materialia
  • Record number

    1143736