Flow stress and work hardening of Mg-Y alloys

Flow stress and work hardening behaviour of Mg-Y binary alloys have been studied under uniaxial tension and compression at 4 K, 78 K and 298 K. Electron microscopy observations show that Yttrium forms multi-atomic clusters distributed randomly in Mg matrix. During thermomechanical processing, Y accu...

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Bibliographic Details
Published in:International journal of plasticity 2017-05, Vol.92, p.96-121
Main Authors: Kula, A., Jia, X., Mishra, R.K., Niewczas, M.
Format: Article
Language:English
Subjects:
Alloy development
Alloys
Atomic clusters
Binary alloys
Compressive properties
Crystal plasticity
Crystals
Deformation
Deformation mechanisms
Dislocations
Ductility
Electron microscopy
Flow stress
Fracture
Fracture surfaces
Grain boundaries
Hardening rate
Magnesium
Magnesium base alloys
Mg-Y alloys
Plastic flow
Recrystallization
Shear stress
Slip
Solid solution strengthening
Solution strengthening
Strength
Thermomechanical treatment
Twinning
Work hardening
Yield strength
Yield stress
Yttrium
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Summary:Flow stress and work hardening behaviour of Mg-Y binary alloys have been studied under uniaxial tension and compression at 4 K, 78 K and 298 K. Electron microscopy observations show that Yttrium forms multi-atomic clusters distributed randomly in Mg matrix. During thermomechanical processing, Y accumulates at the grain boundaries and controls recrystallization texture, which acquires lower intensity of the basal component and higher degree of randomness in comparison to polycrystalline Mg. Tensile and compressive yield stress of the alloys is temperature dependent and decreases as temperature increases from 4 K to 298 K. The grain size and solution strengthening contributions to the yield stress have been analyzed for all alloys and deformation temperatures. Critical resolved shear stress (CRSS) of individual deformation modes has been obtained from the modelling of the flow stress. These results show that Y strengthens most the slip system, followed by pyramidal I, prismatic, twinning and basal systems. All slip systems exhibit monotonic increase of CRSS with Y concentration, but at different rates. Analysis of the solution strengthening component of the yield stress suggests that it is determined by activity of the basal slip participating in yielding. A correlation between the athermal hardening rate, Θh, and the amount of slip in individual deformation modes leads to the conclusion that higher athermal hardening rates are produced by a balanced contribution of basal and non-basal slip, whereas lower Θh is associated typically with less activity of slip. Improved ductility of Mg-Y alloys is reflected in the type of dislocation microstructure developed during plastic flow and the character of the fracture surfaces. These alloys' characteristics are linked to the mechanical property data to obtain better understanding of the mechanisms responsible for the enhanced plasticity of Mg-Y alloys. •Strain hardening and texture evolution of Mg-Y alloys have been studied under uniaxial tension and compression at 298 K, 78 K and 4 K.•The grain size and solution strengthening contributions to the yield stress have been analyzed.•Strengthening of individual deformation modes by Yttrium has been determined form rate-dependent crystal plasticity modeling of the flow stress.•A correlation between work hardening rate and the activity of different slip systems has been studied.•Mg-Y alloys exhibit quasi-brittle trans-granular fracture mode with evidence of Ytt
ISSN:0749-6419
1879-2154
DOI:10.1016/j.ijplas.2017.01.012