Effect of Cr precipitates and He bubbles on the strength of 1 1 0 tilt grain boundaries in BCC Fe: An atomistic study

Dmitry Terentyev, Xinfu He, Lorenzo Malerba

    Research outputpeer-review

    Abstract

    Molecular static simulations were carried out to study the fracture process of different 1 1 0 tilt grain boundaries (Σ19{3 3 1}, Σ9{2 2 1}, Σ3{1 1 1}, Σ3{1 1 2}, Σ11{1 1 3}, Σ9{1 1 4}). The main goal of this work was to investigate variation of the deformation mechanism and fracture stress in the presence of Cr precipitates, voids and He bubbles at the core of the grain boundaries (GBs). The corresponding deformation process was characterized in terms of stress–strain relationship and deformation mechanisms were inspected by visualization tools. Based on the obtained stress–strain curves, the studied GBs can be subdivided into two types, those that exhibit extensive slip and those that do not show slip at all. The presence of Cr precipitates at the GB core increases critical shear stress necessary to initiate the slip, and nucleation of a crack was regularly seen to occur at the precipitate–matrix interface. The effect of voids and He bubbles on the fracture stress is much stronger. It was revealed that the plastic deformation was essentially suppressed. The reason for the suppression was attributed to the emission of the dislocations from voids/bubbles and their pile up.
    Original languageEnglish
    Pages (from-to)925-933
    JournalComputational Materials Science
    Volume50
    Issue number3
    DOIs
    StatePublished - 1 Jan 2011

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