Instability of dislocation fluxes in a single slip: Deterministic and stochastic models of dislocation patterning

Wu, Ronghai; Tüzes, Dániel; Ispánovity, Péter Dusán; Groma, István; Hochrainer, Thomas; Zaiser, Michael

doi:10.1103/physrevb.98.054110

Cited by 35 publications

(32 citation statements)

References 37 publications

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“…A closed mathematical model is then specified by relating the effective shear stresses to the dislocation densities. In line with the single-slip model of Groma and co-workers (Groma et al 2016;Wu et al 2018), we consider the effective driving stresses T s i to result from the combination of sign-dependent local driving stresses τ s,dr i and friction stresses τ s,f i :…”

Section: Model Equationsmentioning

confidence: 99%

“…The considered slip geometry has the peculiarity that this stress is the same in both slip systems and equals the xy component of the stress tensor, τ 1 = τ 2 = σ xy . In our calculations, we consider a bulk system with periodic boundary conditions and calculate this stress from the plastic strain γ using a Green's function formalism (Zaiser and Moretti 2005;Wu et al 2018):…”

Section: Model Equationsmentioning

confidence: 99%

“…To this end we rely on a most basic version of den-sity based dislocation dynamics in multiple-slip conditions. We start from the model used by Zaiser, Groma and co-workers (Groma et al 2016;Wu et al 2018) for analysing the conditions for pattern formation in single slip, and generalize this to symmetrical double slip along lines proposed in earlier work of Groma and co-workers (Yefimov and Van der Giessen 2005;Limkumnerd and der Giessen 2008). This framework not only provides us with some degree of analytical tractability but also with a solid theoretical foundation: The equations we use have been rigorously derived from statistical averaging of the underlying discrete dynamics (Groma et al 2003;Valdenaire et al 2016) and can be related via variational calculus to the statistically averaged energy functional of the dislocation system (Zaiser 2015;Groma et al 2016).…”

Section: Introductionmentioning

confidence: 99%

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Cell structure formation in a two-dimensional density-based dislocation dynamics model

Zaiser

2021

Mater Theory

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Cellular patterns formed by self-organization of dislocations are a most conspicuous feature of dislocation microstructure evolution during plastic deformation. To elucidate the physical mechanisms underlying dislocation cell structure formation, we use a minimal model for the evolution of dislocation densities under load. By considering only two slip systems in a plane strain setting, we arrive at a model which is amenable to analytical stability analysis and numerical simulation. We use this model to establish analytical stability criteria for cell structures to emerge, to investigate the dynamics of the patterning process and establish the mechanism of pattern wavelength selection. This analysis demonstrates an intimate relationship between hardening and cell structure formation, which appears as an almost inevitable corollary to dislocation dominated strain hardening. Specific mechanisms such as cross slip, by contrast, turn out to be incidental to the formation of cellular patterns.

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Section: Model Equationsmentioning

confidence: 99%

Section: Model Equationsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Cell structure formation in a two-dimensional density-based dislocation dynamics model

Zaiser

2021

Mater Theory

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“…So the energy criterion can be written as a function of reacting dislocation density vectors, (1)  and (2)  , the corresponding Burgers vectors, (1) b and , together with the line direction of the junction e , which is a constant vector for each type of junction, by substituting equations (19) and (20) into equation (18). When using the criterion (18), the dislocation density vectors () k  should be consistent with the direction of the intersection vector, which means () 0 k  e  . If not, we can change the sign of both the density () k  and its Burgers vector () k b to make it satisfied, since the physical dislocation does not change by changing the sign of () k  and () k b simultaneously .…”

Section: Line Direction Considerationsmentioning

confidence: 99%

Implementation of annihilation and junction reactions in vector density-based continuum dislocation dynamics

Lin

El–Azab

2020

Modelling Simul. Mater. Sci. Eng.

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In a continuum dislocation dynamics formulation by Xia and El-Azab [1], dislocations are represented by a set of vector density fields, one per crystallographic slip systems. The space-time evolution of these densities is obtained by solving a set of dislocation transport equations coupled with crystal mechanics. Here, we present an approach for incorporating dislocation annihilation and junction reactions into the dislocation transport equations. These reactions consume dislocations and result in nothing as in the annihilation reactions, or produce new dislocations of different types as in the case of junction reactions. Collinear annihilation, glissile junctions, and sessile junctions are particularly emphasized here. A generalized energy-based criterion for junction reactions is established in terms of the dislocation density and Burgers vectors of the reacting species, and the reaction rate terms for junction reactions are formulated in terms of the dislocation densities. In order to illustrate how the dislocation network changes as a result of junction formation and annihilation in a continuum dislocation dynamics setting, we present some numerical examples focusing on the reactions processes themselves. The results show that our modeling approach is able to capture the respective dislocation network changes associated with dislocation reactions: dislocations of opposite line directions encountering each other on collinear slip systems annihilate to connect the dislocations on the two slip systems, glissile junctions form on new slip system behave like Frank-Read sources, and sessile junctions form and expand along the intersection of the slip planes of the reacting dislocation species. A collective-dynamics test showing the frequency of occurrence of junctions of different types relative to each other is also presented.

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“…The components of the dislocation density alignment tensors can be envisaged as density-like fields which contain more and more detailed information about the orientation distribution of dislocations. CDD has been used to simulate various phenomena including dislocation patterning (Sandfeld and Zaiser, 2015;Wu et al, 2017b) and co-evolution of phase and dislocation microstructure (Wu et al, 2017a). The formulation in terms of alignment tensors has proven particularly versatile since one can formulate the elastic energy functional of the dislocation system in terms of dislocation density alignment tensors (Zaiser, 2015) and then use this functional to derive the dislocation velocity in a thermodynamically consistent manner (Hochrainer, 2016).…”

Section: Introductionmentioning

confidence: 99%

Annihilation and sources in continuum dislocation dynamics

Monavari

Zaiser

2018

Mater Theory

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Continuum dislocation dynamics (CDD) aims at representing the evolution of systems of curved and connected dislocation lines in terms of density-like field variables. Here we discuss how the processes of dislocation multiplication and annihilation can be described within such a framework. We show that both processes are associated with changes in the volume density of dislocation loops: dislocation annihilation needs to be envisaged in terms of the merging of dislocation loops, while conversely dislocation multiplication is associated with the generation of new loops. Both findings point towards the importance of including the volume density of loops (or 'curvature density') as an additional field variable into continuum models of dislocation density evolution. We explicitly show how this density is affected by loop mergers and loop generation. The equations which result for the lowest order CDD theory allow us, after spatial averaging and under the assumption of unidirectional deformation, to recover the classical theory of Kocks and Mecking for the early stages of work hardening.

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Instability of dislocation fluxes in a single slip: Deterministic and stochastic models of dislocation patterning

Cited by 35 publications

References 37 publications

Cell structure formation in a two-dimensional density-based dislocation dynamics model

Cell structure formation in a two-dimensional density-based dislocation dynamics model

Implementation of annihilation and junction reactions in vector density-based continuum dislocation dynamics

Annihilation and sources in continuum dislocation dynamics

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