Effects of Ti addition on the microstructure and mechanical properties of Al-Zn-Mg-Cu-Zr alloy

Abstract

The effects of Ti addition (0.1 wt%) on the microstructure evolution and mechanical properties of an Al-7.6Zn-2.6Mg-2.0Cu-0.1Zr alloy were investigated during solidification, extrusion, solution treatment, and aging. The addition of Ti reduces the grain size and degree of phase agglomeration during solidification, thereby improving the strength and ductility of the as-cast alloy. The extrusion forms a bimodal structure consisting of fine dynamically recrystallized (DRXed) grains and coarse elongated unDRXed grains. Ti induces the refinement of the eta-phases that enhances dynamic recrystallization (DRX) by particle-stimulated nucleation, resulting in reduced strength of the as-extruded alloy. The dissolution of the eta-phase occurs in the initial stages of the solution treatment, followed by coarsening of the eta-phase. The solution treatment causes static recrystallization and grain growth, increasing the grain size. The addition of Ti decreases the size and increases the number density of the L1(2) precipitate by modifying the chemical composition of (Al,Zn)(3)Zr into (Al,Zn)(3)(Zr,Ti), and causes the formation of an Al18Mg3Ti2 phase during the solution treatment. The addition of Ti also enhances heterogeneous nucleation of eta-Mg(Zn,Cu,Al)(2) at the Al18Mg3Ti2 interface and grain boundary but has a negligible effect on the formation of nanoprecipitates (GPII zone, eta') in the matrix. The improved strength and ductility of the solution-treated and aged alloys are attributed to the higher number density of the fine L1(2)-(Al,Zn)(3)(Zr,Ti) precipitates and grain refinement, as well as the finer eta-phases acting as cracking sites.