Experimental and Computational Studies of Competitive Precipitation Behavior Observed in Microstructures with High Dislocation Density and Ultra-Fine Grains

Tetsuya Masuda; Shoichi Hirosawa; Z. Horita; Kenji Matsuda

doi:10.4028/www.scientific.net/MSF.706-709.1787

Paper Titles

Numerical Analysis in the Process of Alternate Pressing and Multiaxial Compression
p.1763

Shear Strength Measurement of Gum Metal during High-Pressure Torsion
p.1769

Grain Refinement and Superplastic Deformation Behavior of Zn-Al Alloy
p.1775

Grain Refinement of Magnesium Alloys by CONFORM: A Continuous Severe Plastic Deformation Route?
p.1781

Experimental and Computational Studies of Competitive Precipitation Behavior Observed in Microstructures with High Dislocation Density and Ultra-Fine Grains
p.1787

Enhanced Low-Temperature Impact Toughness of Ultra-Fine Grained SiCp/ZL108 Composites
p.1793

Strengthening of Alloys with Elastic Anisotropy by Severe Plastic Deformation
p.1799

Developing Hardness and Microstructural Homogeneity in High-Pressure Torsion
p.1805

Equal Channel Angular Pressing of Cu-Al Bimetallic Rod
p.1811

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Experimental and Computational Studies of Competitive Precipitation Behavior Observed in Microstructures with High Dislocation Density and Ultra-Fine Grains

Abstract:

The competitive precipitation behavior observed in microstructures with high dislocation density and ultra-fine grains has been studied experimentally and computationally for cold-rolled and severe plastic deformed Al-Mg-Si alloy. The age-hardenability at 443K was reduced by the two deformation processes due to the accelerated formation of larger precipitates on dislocations and grain boundaries, in place of the transgranular precipitation of refined β” in the matrix. The developed numerical model based on the classical heterogeneous nucleation theory clarified the dislocation density and grain size dependences of the volume fraction of precipitates nucleated at different sites, in good agreement with experimental results. It could be therefore possible that three strengthening mechanisms of strain hardening, hardening by grain refinement and precipitation hardening are optimally exploited according to the computationally estimated dependences.