Dislocation glide through non-randomly distributed point obstacles

Classical meso-scale models for dislocation-obstacle interactions have, by and large, assumed a random distribution of obstacles on the glide plane. While a good approximation in many situations, this does not represent materials where obstacles are clustered on the glide plane. In this work, we hav...

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Bibliographic Details
Published in:Philosophical magazine (Abingdon, England) England), 2013-09, Vol.93 (27), p.3664-3679
Main Authors: de Vaucorbeil, A., Sinclair, C.W., Poole, W.J.
Format: Article
Language:English
Subjects:
alloys
Approximation
areal-glide model
Clustering
clusters
Condensed matter: structure, mechanical and thermal properties
Defects and impurities in crystals
microstructure
Dislocations
Exact sciences and technology
Glide
Interaction between different crystal defects
gettering effect
Linear defects: dislocations, disclinations
Obstacles
Physics
Planes
Shear stress
Spatial distribution
strengthening mechanisms
Structure of solids and liquids
crystallography
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Summary:Classical meso-scale models for dislocation-obstacle interactions have, by and large, assumed a random distribution of obstacles on the glide plane. While a good approximation in many situations, this does not represent materials where obstacles are clustered on the glide plane. In this work, we have investigated the statistical problem of a dislocation sampling a set of clustered point obstacles in the glide plane using a modified areal-glide model. The results of these simulations show two clear regimes. For weak obstacles, the spatial distribution does not matter and the critically resolved shear stress is found to be independent of the degree of clustering. In contrast, above a critical obstacle strength determined by the degree of clustering, the critical resolved shear strength becomes constant. It is shown that this behaviour can be explained semi-analytically by considering the probability of interaction between the dislocation line and obstacles at a given level of stress. The consequences for alloys exhibiting solute clustering are discussed.
ISSN:1478-6435
1478-6443
DOI:10.1080/14786435.2013.820384