Crack interaction with nanoscale twinning near a second-phase particle in fine-grained magnesium alloy

Abstract: A theoretical model is established to address the effect of nanoscale twinning near a second-phase particle on crack growth in fine-grained magnesium alloys. The numerical solutions of singular integral equations are obtained by the considering complex variable method of Muskhelishvili, the superposition principle of elasticity, and the distributed dislocation technique. The expressions of stress intensity factors near the left crack tip are derived, and the energy release rate (ERR) characterizing the conditi… Show more

“…The nanotwins could be also initiated by the high stress concentration, and the nanotwins with a large thickness-length ratio have a positive influence in ductile fracture via serving as an energetic energydissipating mechanism, which favors the improvement in fracture toughness. [38,39] Furthermore, the interacted SFs were detected in the composites, resulting in the formation of LCs, as indicated in the TEM image of Figure 6h and HRTEM image of Figure 6i. The high number density of SFs can benefit strain hardening by acting as a barrier to impede the propagation of dislocations and deliver the dynamic Hall-Petch effect.…”

“…The nanotwins could be also initiated by the high stress concentration, and the nanotwins with a large thickness‐length ratio have a positive influence in ductile fracture via serving as an energetic energy‐dissipating mechanism, which favors the improvement in fracture toughness. [ 38,39 ]…”

Improved Strength–Ductility Synergy of a CoCrNi Medium‐Entropy Alloy by Ex Situ TiN Nanoparticles

“…The nanotwins could be also initiated by the high stress concentration, and the nanotwins with a large thickness-length ratio have a positive influence in ductile fracture via serving as an energetic energydissipating mechanism, which favors the improvement in fracture toughness. [38,39] Furthermore, the interacted SFs were detected in the composites, resulting in the formation of LCs, as indicated in the TEM image of Figure 6h and HRTEM image of Figure 6i. The high number density of SFs can benefit strain hardening by acting as a barrier to impede the propagation of dislocations and deliver the dynamic Hall-Petch effect.…”

“…The nanotwins could be also initiated by the high stress concentration, and the nanotwins with a large thickness‐length ratio have a positive influence in ductile fracture via serving as an energetic energy‐dissipating mechanism, which favors the improvement in fracture toughness. [ 38,39 ]…”

Improved Strength–Ductility Synergy of a CoCrNi Medium‐Entropy Alloy by Ex Situ TiN Nanoparticles

Grain boundary segregation-induced strengthening-weakening transition and its ideal maximum strength in nanopolycrystalline FeNiCrCoCu high-entropy alloys