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Kinematics of polycrystal deformation by grain boundary sliding
Publikationstyp
Journal Article
Publikationsdatum
2011-06-01
Sprache
English
Enthalten in
Volume
59
Issue
11
Start Page
4366
End Page
4377
Citation
Acta Materialia 59 (11): 4366-4377 (2011)
Publisher DOI
Scopus ID
Publisher
Elsevier
We analyze the macroscopic deformation of a polycrystalline solid due to local deformation events in the core of grain boundaries. The central result is an equation that decomposes the effective macroscopic strain into contributions from three deformation modes, namely: (i) the elastic strain in the bulk of the crystallites; (ii) the results of dislocation glide and climb processes; and (iii) the deformation events in the grain boundary core. The latter process is represented by jumps in the displacement vector field that can be decomposed into tangential ("slip") and normal ("stretch") components. The relevant measure for the grain-boundary-mediated deformation is not the displacement jump vector but a grain-boundary discontinuity tensor that depends on the displacement jump and on the orientation of the grain boundary normal. Accommodation processes at triple junctions do not contribute significantly to the macroscopic strain. By means of example, the theory is applied to the effective elastic response of nanocrystalline materials with an excess slip compliance at grain boundaries. The predictions, specifically on the size dependence of the Poisson ratio, agree with recent experiments on nanocrystalline Pd. The value of the slip compliance for grain boundaries in Pd is obtained as 18 pm GPa-1.
Schlagworte
Grain boundaries
Nanocrystalline materials
Plastic deformation
DDC Class
530: Physics