Yield vertices for {123}〈111〉 multiple slip

Abstract: The single-crystal yield surfaces of bcc crystals for slip on {123}͗111͘ systems have been analyzed systematically and derived based on the Taylor/Bishop-Hill theory. It is found that there are 338 stress states altogether. All the stress states are classified according to the crystal symmetry. The results demonstrated that there are 14 groups of yield vertices, which activate five, six, or eight slip systems, depending on the crystallographically nonequivalent groups. In addition, the four groups of yield ver… Show more

“…It means that, for different orientations with the same deformation, the greater the M value is, the more difficult the deformation will be. Using the maximum work principle of Bishop-Hill and all the possible yield stress states (including slip or/and twinning yield stresses), the 5 dimensional yield stress states (the definition of notations is seen in reference [15] ) and corresponding active slip or/and twinning systems (the definition of notations is seen in ref. [11]) for arbitrary orientations in the standard stereographic triangle of cubic crystal orientations under axisymmetric ξ > , as shown in Table 1), the results show that the standard stereographic triangle (it can represent all tension or compression axial orientations when symmetry is considered) can be divided into 5 certain regions, each of them is activated by a specific yield stress states respectively.…”

Analysis for twinning and slip in face-centered cubic crystals under axisymmetric co-deformation

“…It means that, for different orientations with the same deformation, the greater the M value is, the more difficult the deformation will be. Using the maximum work principle of Bishop-Hill and all the possible yield stress states (including slip or/and twinning yield stresses), the 5 dimensional yield stress states (the definition of notations is seen in reference [15] ) and corresponding active slip or/and twinning systems (the definition of notations is seen in ref. [11]) for arbitrary orientations in the standard stereographic triangle of cubic crystal orientations under axisymmetric ξ > , as shown in Table 1), the results show that the standard stereographic triangle (it can represent all tension or compression axial orientations when symmetry is considered) can be divided into 5 certain regions, each of them is activated by a specific yield stress states respectively.…”

Analysis for twinning and slip in face-centered cubic crystals under axisymmetric co-deformation

Analysis of crystallographic twinning and slip in fcc crystals under plane strain compression