On the three-dimensional spatial correlations of curved dislocation systems

Coarse-grained descriptions of dislocation motion in crystalline metals inherently represent a loss of information regarding dislocation-dislocation interactions. In the present work, we consider a coarse-graining framework capable of re-capturing these interactions by means of the dislocation-dislo...

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Bibliographic Details
Published in:Materials theory 2021-03, Vol.5 (1), p.1-34, Article 1
Main Authors: Anderson, Joseph Pierre, El-Azab, Anter
Format: Article
Language:English
Subjects:
Characterization and Evaluation of Materials
Characterization of Dislocation Ensembles: Measures and Complexity
Chemistry and Materials Science
Coarse-graining
Condensed Matter Physics
Continuum
Convolution
Correlation
Crystal dislocations
Dislocation
Dislocation density
Granulation
Homogeneity
Materials Engineering
Materials Science
Original Article
Physical Chemistry
Plastic deformation
Slip
Statistical
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Summary:Coarse-grained descriptions of dislocation motion in crystalline metals inherently represent a loss of information regarding dislocation-dislocation interactions. In the present work, we consider a coarse-graining framework capable of re-capturing these interactions by means of the dislocation-dislocation correlation functions. The framework depends on a convolution length to define slip-system-specific dislocation densities. Following a statistical definition of this coarse-graining process, we define a spatial correlation function which will allow the arrangement of the discrete line system at two points—and thus the strength of their interactions at short range—to be recaptured into a mean field description of dislocation dynamics. Through a statistical homogeneity argument, we present a method of evaluating this correlation function from discrete dislocation dynamics simulations. Finally, results of this evaluation are shown in the form of the correlation of dislocation densities on the same slip-system. These correlation functions are seen to depend weakly on plastic strain, and in turn, the dislocation density, but are seen to depend strongly on the convolution length. Implications of these correlation functions in regard to continuum dislocation dynamics as well as future directions of investigation are also discussed.
ISSN:2509-8012
2509-8012
DOI:10.1186/s41313-020-00026-w