Kadkhodapour J, Butz A, Ziaei-Rad S, Schmauder S. Anisotropy of yielding/hardening and microinhomogeneity of deforming/rotating for a polycrystalline metal under cyclic tension–compression. On the prediction of yield surfaces by the crystal plasticity models for fcc polycrystals. Influence of cold rolling reduction on the deformation behaviour and crystallographic orientation development. 2014 81:79.ĭeng GY, Tieu AK, Si LY, Su LH, Lu C, Wang H, Liu M, Zhu HT, Liu XH. Influence of outer corner angle (OCA) on the plastic deformation and texture evolution in equal channel angular pressing. Virtual material testing for stamping simulations based on polycrystal plasticity. Kraska M, Doig M, Tikhomirov D, Raabe D, Roters F. Incorporation of deformation twinning in crystal plasticity models. Simulation of the rolling and shear texture of brass by the Taylor theory adapted for mechanical twinning. Cambridge: Massachusetts Institute of Technology 1992. Polycrystal plasticity: constitutive modeling and deformation processing. Material rate dependence and localized deformation in crystalline solids. Constitutive analysis of elastic–plastic crystals at arbitrary strain. In: Stephen Timoshenko 60th Anniversary Volume.
Analysis of plastic strain in a cubic crystal. Orientation-dependent indentation response of magnesium single crystals: modeling and experiments.
Selvarajou B, Shin JH, Ha TK, Choi IS, Joshi SP, Han HN. Anisotropic deformation induced by spherical indentation of pure Mg single crystals. Kitahara H, Mayama T, Okumura K, Tadano Y, Tsushida M, Ando S. Incipient plasticity and deformation mechanisms in single-crystal Mg during spherical nanoindentation. 2016 650:20.Ĭatoor D, Gao YF, Geng J, Prasad MJ, Herbert EG, Kumar KS, Pharr GM, George EP. Acoustic emission study on the activity of slip and twin mechanisms during compression testing of magnesium single crystals. Analysis of crystallographic orientation changes during deformation of magnesium single crystals. Cambridge: Massachusetts Institute of Technology 1966. Plane-strain compression of magnesium and magnesium alloy crystals. Effect of rare earth additions on the critical resolved shear stresses of magnesium alloys. Herrera-Solaz V, Hidalgo-Manrique P, Pérez-Prado MT, Letzig D, Llorca J, Segurado J. Magnesium and its alloys as orthopedic biomaterials: a review. Staiger MP, Pietak AM, Huadmai J, Dias G. Magnesium and its alloys applications in automotive industry. The effort on the study of magnesium single crystal in the present work contributes to further polycrystalline analysis. Basal slip is found to be easily activated due to a slight deviation, while a slight deviation in the twin-favored case could result in a significant difference in the mechanical behavior after the reorientation. Furthermore, the effect of an initial deviation angle on the mechanical responses was evaluated, which is proved to be also orientation-dependent. It is also found in the simulation that basal slip in the twinned region is active even before the saturation of twin activity in a twin-favored case. The predicted macro-and microscopic responses, along with the experimental results, show strong orientation-dependent properties. Related material parameters were calibrated at first according to the classical channel-die tests. The proposed model was then applied to the simulation of plane-strain compression deformation for different orientations. Twin-induced lattice reorientation was also incorporated in the model. Four deformation mechanisms (including basal 〈 a〉, prismatic 〈 a〉, pyramidal 〈 c + a〉 slip and tension twin) and their interactions were considered. A phenomenological crystal plasticity constitutive model for magnesium single crystal was presented.
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