The increasing demand for materials with well-defined microstructure, accompanied by the advancing miniaturization of devices, is the reason for the growing interest in physically motivated, dislocation-based continuum theories of plasticity. In recent years, various advanced continuum theories have been introduced, which are able to described the motion of straight and curved dislocation lines. The focus of this paper is the question of how to include fundamental properties of discrete dislocations during their motion and interaction in a continuum dislocation dynamics (CDD) theory. In our CDD model, we obtain elastic interaction stresses for the bundles of dislocations by a mean-field stress, which represents long-range stress components,...
A framework for investigating plasticity phenomena and their dependence on the underlying physical a...
We derive a continuum model for the dynamics of a dislocation array that consists of dislocations in...
The plastic deformation of metals is the result of the motion and interaction of dislocations, line ...
Dislocation motion in the crystal lattice of materials is the basis for macroscopic plasticity. Whil...
In this contribution we discuss the problem of a dislocation double pileup at impenetrable boundarie...
Continuum frameworks of dislocation-based plasticity theories are gaining prominence in the research...
To develop a continuum theory based on the evolution of dislocation microstructures, two challenges ...
The Continuum Dislocation Dynamics theory (CDD) of crystal plasticity, utilizing a second-order disl...
Miniaturization of components and devices calls for an increased effort on physically motivated cont...
The development of advanced materials is driven by continuous progress in the synthesis and control ...
Modeling dislocation interaction on a mesoscopic scale is an important task for the description of f...
One of the main targets in the development of dislocation based continuum crystal plasticity theorie...
The Continuum Dislocation Dynamics theory (CDD) of crystal plasticity, utilizing a second-order disl...
Crystal plasticity is governed by the motion of lattice dislocations. Although continuum theories of...
In this chapter, a rigorous analysis is given as a reference in which dislocations are treated as di...
A framework for investigating plasticity phenomena and their dependence on the underlying physical a...
We derive a continuum model for the dynamics of a dislocation array that consists of dislocations in...
The plastic deformation of metals is the result of the motion and interaction of dislocations, line ...
Dislocation motion in the crystal lattice of materials is the basis for macroscopic plasticity. Whil...
In this contribution we discuss the problem of a dislocation double pileup at impenetrable boundarie...
Continuum frameworks of dislocation-based plasticity theories are gaining prominence in the research...
To develop a continuum theory based on the evolution of dislocation microstructures, two challenges ...
The Continuum Dislocation Dynamics theory (CDD) of crystal plasticity, utilizing a second-order disl...
Miniaturization of components and devices calls for an increased effort on physically motivated cont...
The development of advanced materials is driven by continuous progress in the synthesis and control ...
Modeling dislocation interaction on a mesoscopic scale is an important task for the description of f...
One of the main targets in the development of dislocation based continuum crystal plasticity theorie...
The Continuum Dislocation Dynamics theory (CDD) of crystal plasticity, utilizing a second-order disl...
Crystal plasticity is governed by the motion of lattice dislocations. Although continuum theories of...
In this chapter, a rigorous analysis is given as a reference in which dislocations are treated as di...
A framework for investigating plasticity phenomena and their dependence on the underlying physical a...
We derive a continuum model for the dynamics of a dislocation array that consists of dislocations in...
The plastic deformation of metals is the result of the motion and interaction of dislocations, line ...