The objective of this study was to identify the microstructural mechanisms related to the high strength and ductile behavior of 2139-Al, and how dynamic conditions would affect the overall behavior of this alloy. Three interrelated approaches, which span a spectrum of spatial and temporal scales, were used: (i) The mechanical response was obtained using the split Hopkinson pressure bar, for strain-rates ranging from 1.0×103s to 1.0×104s1. (ii) First principles density functional theory calculations were undertaken to characterize the structure of the interface and to better understand the role played by Ag in promoting the formation of the Ω phase for several Ω-Al interface structures. (iii) A specialized microstructurally based finite element analysis and a dislocation-density based multiple-slip formulation that accounts for an explicit crystallographic and morphological representation of Ω and θ precipitates and their rational orientation relations were conducted. The predictions from the microstructural finite element model indicated that the precipitates continue to harden and also act as physical barriers that impede the matrix from forming large connected zones of intense plastic strain. As the microstructural FE predictions indicated, and consistent with the experimental observations, the combined effects of θ and Ω, acting on different crystallographic orientations, enhance the strength and ductility, and reduce the susceptibility of 2139-Al to shear strain localization due to dynamic compressive loads.

Issue Section:
Advances in Impact Engineering
Keywords:
aluminium alloys, compressive strength, crystal microstructure, crystal morphology, crystal orientation, density functional theory, dislocation density, finite element analysis, interface structure, plastic deformation
Topics:
Alloys, Aluminum, Crystals, Density functional theory, Dislocation density, Ductility, Finite element analysis, Finite element model, Interface structure, Shear (Mechanics), Stress, Deformation, Pressure, Modeling, Plasticity
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