Improved phase field model of dislocation intersections

Zheng, Songlin; Zheng, Dongchang; Ni, Yong; He, Linghui

doi:10.1038/s41524-018-0075-x

Cited by 20 publications

(4 citation statements)

References 40 publications

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“…This method has evolved from the original Landau approach to the modeling of phase transitions [150][151][152][153][154][155]. In PFDD lattice slips are described by scalar order parameters and the energy wells represent quantized lattice invariant shears [147,156,157]; transition layers, separating regions with different amount of shear, represent the locations of dislocation lines. The Landau energy functional couples the tensorial linear elastic energy with the scalar lattice energy whose periodic structure is usually informed by atomic scale simulations based on the Cauchy-Born rule.…”

Section: Some Backgroundmentioning

confidence: 99%

Discontinuous yielding of pristine micro-crystals

Salman¹,

Baggio²,

Bacroix³

et al. 2021

Comptes Rendus. Physique

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We study the mechanical response of a dislocation-free 2D crystal under homogenous shear using a new mesoscopic approach to crystal plasticity, a Landau-type theory, accounting for the global invariance of the energy in the space of strain tensors while operating with an infinite number of equivalent energy wells. The advantage of this approach is that it eliminates arbitrariness in dealing with topological transitions involved, for instance, in nucleation and annihilation of dislocations. We use discontinuous yielding of pristine micro-crystals as a benchmark problem for the new theory and show that the nature of the catastrophic instability, which in this setting inevitably follows the standard affine response, depends not only on lattice symmetry but also on the orientation of the crystal in the loading device. The ensuing dislocation avalanche involves cooperative dislocation nucleation, resulting in the formation of complex microstructures controlled by a nontrivial self-induced coupling between different plastic mechanisms.

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Section: Some Backgroundmentioning

confidence: 99%

Discontinuous yielding of pristine micro-crystals

Salman¹,

Baggio²,

Bacroix³

et al. 2021

Comptes Rendus. Physique

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“…In 2014, Shen et al [18] proposed the microscopic phase-field model in which all order parameter evolution is confined to the slip planes and the gradient energy is removed from the system energy. More recently, Zheng et al [19] modified the crystalline energy to fully account for the reactions between dislocations gliding in intersecting slip planes, while also neglecting the gradient energy.…”

Section: Introductionmentioning

confidence: 99%

A comparison of different continuum approaches in modeling mixed-type dislocations in Al

Smith

Mianroodi

et al. 2019

Modelling Simul. Mater. Sci. Eng.

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Mixed-type dislocations are prevalent in metals and play an important role in their plastic deformation. Key characteristics of mixed-type dislocations cannot simply be extrapolated from those of dislocations with pure edge or pure screw characters. However, mixed-type dislocations traditionally received disproportionately less attention in the modeling and simulation community. In this work, we explore core structures of mixed-type dislocations in Al using three continuum approaches, namely, the phase-field dislocation dynamics (PFDD) method, the atomistic phase-field microelasticity (APFM) method, and the concurrent atomistic-continuum (CAC) method. Results are benchmarked against molecular statics. We advance the PFDD and APFM methods in several aspects such that they can better describe the dislocation core structure. In particular, in these two approaches, the gradient energy coefficients for mixed-type dislocations are determined based on those for pure-type ones using a trigonometric interpolation scheme, which is shown to provide better prediction than a linear interpolation scheme. The dependence of the inslip-plane spatial numerical resolution in PFDD and CAC is also quantified.

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“…Some studies report how the phase field is coupled with isotropic plasticity [27] or CP [28] to analyze the finite or infinitesimal strains in larger material volumes. Recent studies also show an increasing trend towards discrete-dislocation-dynamics-based phase field models [29,30,31,32,33,34,35,36] to describe plastic deformation, but such models can only be applied to smaller systems due to the associated computational cost. The non-homogeneous deformation in the framework of phase field modeling has, however, been addressed by only a few researchers, who employed strain-gradient CP coupled with a phase field model like, for example, the work by Aldakheel on fracture analysis of metals [37].…”

Section: Introductionmentioning

confidence: 99%

Studying Grain Boundary Strengthening by Dislocation-Based Strain Gradient Crystal Plasticity Coupled with a Multi-Phase-Field Model

et al. 2019

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One ambitious objective of Integrated Computational Materials Engineering (ICME) is to shorten the materials development cycle by using computational materials simulation techniques at different length scales. In this regard, the most important aspects are the prediction of the microstructural evolution during material processing and the understanding of the contributions of microstructural features to the mechanical response of the materials. One possible solution to such a challenge is to apply the Phase Field (PF) method because it can predict the microstructural evolution under the influence of different internal or external stimuli, including deformation. To accomplish this, it is necessary to take into account plasticity or, specifically, non-homogeneous plastic deformation, which is particularly important for investigating the size effects in materials emerging at the micron length scale. In this work, we present quasi-2D simulations of plastic deformation in a face centred cubic system using a finite strain formulation. Our model consists of dislocation-based strain gradient crystal plasticity implemented into a PF code. We apply this model to study the influence of grain size on the mechanical behavior of polycrystals, which includes dislocation storage and annihilation. Furthermore, the initial state of the material before deformation is also considered. The results show that a dislocation-based strain gradient crystal plasticity model can capture the Hall-Petch effect in many aspects. The model reproduced the correct functional dependence of the flow stress of the polycrystal on grain size without assigning any special properties to the grain boundaries. However, the predicted Hall-Petch coefficients are significantly smaller than those found typically in experiments. In any case, we found a good qualitative agreement between our findings and experimental results.

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Improved phase field model of dislocation intersections

Cited by 20 publications

References 40 publications

Discontinuous yielding of pristine micro-crystals

Discontinuous yielding of pristine micro-crystals

A comparison of different continuum approaches in modeling mixed-type dislocations in Al

Studying Grain Boundary Strengthening by Dislocation-Based Strain Gradient Crystal Plasticity Coupled with a Multi-Phase-Field Model

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