Roles of triple and quadruple junctions on plasticity by phase-field crystal approach

Roles of non-/symmetric triple and quadruple junctions on plasticity of ploycrystals are examined using phasefiled crystal model combined with an isovolumetric deformation technique. We designed four polycrystalline samples containing the four types of junctions respectively to simulate the deformation process under a strain rate comparable to practical situations. Our results uncover relationships between the ability of resistances to external deformations and the deformation mechanisms. For the ploycrystals containing quadruple junctions, the symmetric junction is beneficial to maintain the stability of the junctions during deformations, while asymmetric ones would be disjointed and result in formation and growth of sub-grains. For the polycrystals containing triple junctions, the stability of the junction is strongly related to the misorientation angles of the associated grains. The triple junction composed with high-angle GBs exhibits excellent stability under successive deformations and the deformation is dominated by GB migrations. Low-angle GBs migrate more easily than the high-angle ones.

Automated summary

The roles of non-/symmetric triple and quadruple junctions on the plasticity of polycrystals are examined using a phasefield crystal model. It is found that symmetric quadruple junctions contribute to the stability of the junctions during deformations, while asymmetric ones result in the formation and growth of sub-grains. The stability of triple junctions is strongly related to the misorientation angles of the associated grains.