Litcius/Paper detail

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

Ronghai Wu, Michael Zaiser

2021Materials Theory31 citationsDOIOpen Access PDF

Abstract

Abstract 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.

Topics & Concepts

DislocationCell structureHardening (computing)CorollaryMaterials scienceSlip (aerodynamics)Cell formationMicrostructureStrain hardening exponentPattern formationCrystallographyMechanicsStatistical physicsBiological systemMathematicsPhysicsNanotechnologyChemistryComposite materialThermodynamicsMathematical optimizationPure mathematicsBiologyLayer (electronics)GeneticsMicrostructure and mechanical propertiesForce Microscopy Techniques and ApplicationsHigh-Velocity Impact and Material Behavior
Cell structure formation in a two-dimensional density-based dislocation dynamics model | Litcius