David Lunt scite author profile

Micro slip activation and localization in Ti-6Al-4V deformed in tension have been examined quantitatively using high-resolution (HR) digital image correlation (DIC), HR-electron backscatter diffraction (EBSD) and crystal plasticity finite element modelling. The measured polycrystal slip, strain, lattice rotation and geometrically necessary dislocation (GND) density distributions are generally well captured by the a priori crystal plasticity model based on the rate-sensitive properties of α-titanium. An overall slip trace analysis showed over 80% agreement between HR-DIC and crystal plasticity modelling of the primary slip activation. The texture beneath the characterised free-surface has been found to affect the local slip, stress distribution, lattice curvature and GND density and three texture variations have been considered. Grain-level slip trace analysis shows that the crystal plasticity modelling can capture single (straight) slip, multiple slip activation and complex wavy slip. The latter has been found to result from the interaction of independently activated basal and prismatic slip systems with common slip direction. Initial inter-granular misorientations greater than about 5 o have been shown to influence the subsequent micromechanical grain behaviour including slip, lattice rotation and GND density. This work contributes to the understanding of slip localization and load shedding in dwell fatigue in polycrystalline hexagonal materials.

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Effect of nanoscale α2 precipitation on strain localisation in a two-phase Ti-alloy

Lunt

Busolo

et al. 2017

Acta Materialia

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Many commercial Ti-alloys contain 6 wt.% Aluminium and these alloys are prone to precipitation of α 2 (Ti 3 Al). Here, we investigate and quantify the effect of α 2 precipitation on strain localisation behaviour for Ti-6Al-4V with an equiaxed microstructure using High Resolution Digital Image Correlation (HR-DIC) in combination with Electron Back Scatter Diffraction (EBSD). HR-DIC has enabled us to quantify strain localisation, which shows that at 1% applied strain the strain heterogeneity in terms of maximum shear strain is about twice in the sample containing α 2 precipitates compared to the α 2-free sample. Theoretical slip trace angles for all possible slip systems were calculated using Electron Back Scatter Diffraction (EBSD) orientation data and cross-correlated with experimental slip trace angles measured from nanoscale shear strain maps recorded by HR-DIC to predict the active slip domain. It has been found that while slip type activity in terms of frequency is strongly dependent on texture in respect to loading direction, the actual shear strain contribution from prismatic slip does increase significantly in the presence of α 2 precipitation. This experimental observation supports previous calculations of Anti-Phase Boundary (APB) energies for α 2 precipitates [1] where widely dissociated partial dislocations on the prismatic plane show a lower APB energy than the APB energy associated with shearing on the basal plane in α 2 .

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Microscopic strain localisation in Ti-6Al-4V during uniaxial tensile loading

Lunt

Fonseca

Rugg

et al. 2017

Materials Science and Engineering: A

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David Lunt

How magnesium accommodates local deformation incompatibility: A high-resolution digital image correlation study

Quantitative investigation of micro slip and localization in polycrystalline materials under uniaxial tension

Effect of nanoscale α2 precipitation on strain localisation in a two-phase Ti-alloy

Microscopic strain localisation in Ti-6Al-4V during uniaxial tensile loading

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