A resolution-dependent formulation of dislocation density fields based on orientation fluctuation statistics shows the line bundle closure accurately describes data for coarse-graining lengths up to half the dislocation spacing while the maximum entropy closure does not.
Dislocation transport and line length increase in averaged descriptions of dislocations
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abstract
Crystal plasticity is the result of the motion and interaction of dislocations. There is, however, still a major gap between microscopic and mesoscopic simulations and continuum crystal plasticity models. Only recently a higher dimensional dislocation density tensor was defined which overcomes some drawbacks of earlier dislocation density measures. The evolution equation for this tensor can be considered as a continuum version of dislocation dynamics. We use this evolution equation to develop evolution equations for the total dislocation density and an average curvature which together govern a faithful representation of the dislocation kinematics without having to use extra dimensions.
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cond-mat.mtrl-sci 1years
2025 1verdicts
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The line bundle regime and the scale-dependence of continuum dislocation dynamics
A resolution-dependent formulation of dislocation density fields based on orientation fluctuation statistics shows the line bundle closure accurately describes data for coarse-graining lengths up to half the dislocation spacing while the maximum entropy closure does not.