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Computationally efficient and quantitatively accurate multiscale simulation of solid-solution strengthening by ab initio calculation

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    0450467 - ÚFM 2016 RIV GB eng J - Journal Article
    Ma, D. - Friák, Martin - von Pezold, J. - Raabe, D. - Neugebauer, J.
    Computationally efficient and quantitatively accurate multiscale simulation of solid-solution strengthening by ab initio calculation.
    Acta Materialia. Roč. 85, FEB (2015), s. 53-66. ISSN 1359-6454. E-ISSN 1873-2453
    Institutional support: RVO:68081723
    Keywords : Solid-solution strengthening * DFT * Peierls–Nabarro model * Ab initio * Al alloys
    Subject RIV: BM - Solid Matter Physics ; Magnetism
    Impact factor: 5.058, year: 2015

    We propose an approach for the computationally efficient and quantitatively accurate prediction of solid-solution strengthening. It combines the 2-D Peierls–Nabarro model and a recently developed solid-solution strengthening model. Solid-solution strengthening is examined with Al–Mg and Al–Li as representative alloy systems, demonstrating a good agreement between theory and experiments within the temperature range in which the dislocation motion is overdamped. Through a parametric study, two guideline maps of the misfit parameters against (i) the critical resolved shear stress, s0, at 0 K and (ii) the energy barrier, DEb, against dislocation motion in a solid solution with randomly distributed solute atoms are created. With these two guideline maps, s0 at finite temperatures is predicted for other Al binary systems, and compared with available experiments, achieving good agreement.
    Permanent Link: http://hdl.handle.net/11104/0251778

     
     
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