Numerical simulations of mixed-mode (I and II) notch tip fields in basal-textured magnesium alloys

Crystal plasticity based finite element (CPFE) simulations employing Taylor homogenization for a basal-textured Mg alloy are performed under plane strain, small scale yielding (SSY) conditions to study mixed-mode (I and II) notch tip fields. Two notch orientations are considered. In one case, the no...

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Bibliographic Details
Published in:Journal of the mechanics and physics of solids 2022-02, Vol.159, p.104717, Article 104717
Main Authors: Vaishakh, K.V., Narasimhan, R.
Format: Article
Language:English
Subjects:
Basal texture
Computer simulation
CPFE
Flat surfaces
Fracture mechanics
Fracture toughness
Magnesium alloy
Magnesium base alloys
Mathematical models
Mode mixity
Plane strain
Plastic anisotropy
Plastic deformation
Plastic properties
Plastic zones
Rolling direction
Slip/twin
Stress intensity factors
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Summary:Crystal plasticity based finite element (CPFE) simulations employing Taylor homogenization for a basal-textured Mg alloy are performed under plane strain, small scale yielding (SSY) conditions to study mixed-mode (I and II) notch tip fields. Two notch orientations are considered. In one case, the notch line and normal to the flat surfaces of the notch are taken parallel to the transverse direction (TD) and rolling direction (RD), whereas in the other, they are aligned with normal direction (ND) and TD. The results are compared against those obtained from an isotropic (von Mises) plasticity model with identical stress–strain behavior under RD tension. The maximum plastic zone size at a given level of effective stress intensity factor |K|, enhances with mode II component (i.e., with decrease in mode mixity parameter Me), and is larger for ND–TD orientation. Further, {101̄2} or tensile twinning (TT) occurs near the stretched part of the notch surface, and is more profuse as Me reduces especially for the ND–TD case. It is found that for a given Me, the notch orientation can profoundly affect the distribution of equivalent plastic strain and hydrostatic stress around the notch tip, which underscores the importance of plastic anisotropy of Mg alloys. Finally, by employing appropriate fracture criteria and the computed near-tip fields, the variations of fracture toughness and operative fracture mechanism with Me are predicted for the TD–RD case, which corroborate well with a recent experimental study. •Mixed-mode (I/II) SSY crack tip fields analyzed in a rolled Mg alloy using CPFEA.•Alloy texture and mechanical response represented through Taylor homogenization.•Near-tip stresses, plastic slip and twin intensity influenced by notch orientation.•Experimentally observed crack paths, fracture mechanisms explained from results.•Jc versus mode-mixity predicted from results corroborates well with experiments.
ISSN:0022-5096
1873-4782
DOI:10.1016/j.jmps.2021.104717