Plastic deformation of crystalline materials is governed by the features of stress-driven motion of dislocations. In the case of irradiated steels subject to applied stresses, small dislocation loops as well as precipitates are known to interfere with the dislocation motion, leading to an increased yield stress as compared to pure crystals. We study the combined effect of precipitates and interstitial glissile ½〈111〉 dislocation loops on the yield stress of iron, using large-scale three-dimensional discrete dislocation dynamics simulations. Precipitates are included in the simulations using our recent multi-scale implementation [A. Lehtinen et al., Phys. Rev. E 93 (2016) 013309], where the strengths and pinning mechanisms of the precipitates are determined from molecular dynamics simulations. In the simulations we observe dislocations overcoming precipitates with an atypical Orowan mechanism which results from pencil-glide of screw segments in iron. Even if the interaction mechanisms with dislocations are quite different, our results suggest that in relative terms, precipitates and loops of similar sizes contribute equally to the yield stress in multi-slip conditions.
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机译:晶体材料的塑性变形受位错应力驱动运动的特征支配。在辐照钢承受外加应力的情况下,已知小位错环以及析出物会干扰位错运动,与纯晶体相比,导致屈服应力增加。我们使用大规模的三维离散位错动力学模拟研究了析出物和组织间的可挠性½〈111〉位错环对铁的屈服应力的综合影响。使用我们最近的多尺度实施方案,降水包括在模拟中[A. Lehtinen等,Phys。 Rev. E 93(2016)013309],其中沉淀物的强度和钉扎机理由分子动力学模拟确定。在模拟中,我们观察到位错通过非典型的Orowan机制克服了沉淀,这是由铁中的螺旋段的铅笔滑行引起的。即使具有位错的相互作用机制相差很大,我们的结果也表明,相对而言,相似大小的析出物和环在多滑移条件下对屈服应力的贡献相同。
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