S. Haouala scite author profile

The effect of grain size on the flow stress of FCC polycrystals is analyzed by means of a multiscale strategy based on computational homogenization of the polycrystal aggregate. The mechanical behavior of each crystal is given by a dislocation-based crystal plasticity model in which the critical resolved shear stress follows the Taylor model. The generation and annihilation of dislocations in each slip system during deformation is given by the KocksMecking model, which was modified to account for the dislocation storage at the grain boundaries. Polycrystalline Cu is selected to validate the simulation strategy and all the model parameters are obtained from dislocation dynamics simulations or experiments at lower length scales and the simulation results were in good agreement with experimental data in the literature. The model is applied to explore the influence of different microstructural factors (initial dislocation density, width of the grain size distribution, texture) on the grain size effect. It is found that the initial dislocation density, ρ i , plays a dominant role in the magnitude of the grain size effect and that dependence of flow stress with an inverse power of grain size (σ y − σ ∞ ∝ d −x g ) breaks down for large initial dislocation densities (> 10 14 m −2 ) and grain sizes d g > 40 µm in FCC metals. However, it was found that the grain size con- * Corresponding author Accepted for publication in Acta Materialia (2018) January 17, 2018arXiv:1801.05155v1 [cond-mat.mtrl-sci] 16 Jan 2018 tribution to the strength followed a power-law function of the dimensionless parameter d g √ ρ i for small values of the applied strain (< 2 %), in agreement with previous theoretical considerations for size effects in plasticity.

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An analysis of the influence of the precipitate type on the mechanical behavior of Al - Cu alloys by means of micropillar compression tests

Bellón

Haouala

LLorca

2020

Acta Materialia

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Grain boundary strengthening of FCC polycrystals

2019

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The effect of grain size on the flow strength of FCC polycrystals was analyzed by means of computational homogenization. The mechanical behavior of each grain was dictated by a dislocation-based crystal plasticity model in the context of finite strain plasticity and takes into the account the formation of pile-ups at grain boundaries. All the model parameters have a clear physical meaning and were identified for different FCC metals from dislocation dynamics simulations or experiments. It was found that the influence of the grain size on the flow strength of FCC polycrystals was mainly dictated by the similitude coefficient K that establishes the relationship between the dislocation mean free path and the dislocation density in the bulk. Finally, the modelling approach was validated by comparison with experimental results of the effect of grain size on the flow strength of Ni, Al, Cu and Ag.

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Modeling and algorithms for two-scale time homogenization of viscoelastic-viscoplastic solids under large numbers of cycles

Haouala

Doghri

2015

International Journal of Plasticity

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Effect of slip transmission at grain boundaries in Al bicrystals

Haouala

Alizadeh

Bieler

et al. 2020

International Journal of Plasticity

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The effect of slip transfer on the deformation mechanisms of Al bicrystals was explored using a rate-dependent dislocation-based crystal plasticity model. Three different types of grain boundaries (GBs) were included in the model by modifying the rate of dislocation accumulation near the GB in the Kocks-Mecking law, leading to fully-opaque (dislocation blocking), fully-transparent and partially-transparent GBs. In the latter, slip transmission is only allowed in pairs of SS in neighbour grains that are suitably oriented for slip transfer according to the Luster-Morris parameter. Modifications of the GB character led to important changes in the deformation mechanisms at the GB. In general, bicrystals with fully-opaque boundaries showed an increase in the dislocation density near the GB, which was associated with an increase in the Von Mises stress. In contrast, the dislocation pile-ups and the stress concentration were less pronounced in the case of partially-transparent boundaries as the slip in one grain can progress into the next grain with some degree of continuity. No stress concentrations were found at these boundaries for fully-transparent boundaries, and there was continuity of strain across the boundary, which is not typical of most experimentally observed GBs (Hémery et al., 2018;Bieler et al., 2019). Simulations of ideal bicrystals oriented for favorable slip transfer on the most highly favored slip system in grains with high Schmid factors for slip transfer depends on the number of active SS in * Corresponding author. operation in the neighborhood and that most boundaries will lead to nearly opaque conditions while some boundaries will be transparent. Finally, the model was applied to a particular experimentally observed GB in which slip transfer was clearly operating indicating that the model predicted a nearly transparent GB.

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S. Haouala

An analysis of the influence of grain size on the strength of FCC polycrystals by means of computational homogenization

An analysis of the influence of the precipitate type on the mechanical behavior of Al - Cu alloys by means of micropillar compression tests

Grain boundary strengthening of FCC polycrystals

Modeling and algorithms for two-scale time homogenization of viscoelastic-viscoplastic solids under large numbers of cycles

Effect of slip transmission at grain boundaries in Al bicrystals

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