Theoretical interpretation of abnormal ultrafine-grained material deformation dynamics

Some recent experiments with ultrafine-grained metal samples reveal that it has an abnormal mechanical response on the intensive dynamical loading caused by its impact or electron beam irradiations. On the basis of the original plasticity model, which takes into account dislocation slip and grain bo...

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Bibliographic Details
Published in:Modelling and simulation in materials science and engineering 2016-02, Vol.24 (2), p.25013-25032
Main Authors: Borodin, Elijah N, Mayer, Alexander E
Format: Article
Language:English
Subjects:
Computer simulation
Dislocations
Dynamics
Grain boundary sliding
high strain rates
Inverse
inverse Hall-Petch relation
Mathematical models
Molecular dynamics
Plasticity
ultrafine-grained materials
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Summary:Some recent experiments with ultrafine-grained metal samples reveal that it has an abnormal mechanical response on the intensive dynamical loading caused by its impact or electron beam irradiations. On the basis of the original plasticity model, which takes into account dislocation slip and grain boundary sliding, we show that this response is usual for such structure. Moreover, our calculations predict an inverse Hall-Petch relation for ultrafine grained metals at extremely high strain rates (above 107 s−1), while the classical low strain rate experiments and molecular dynamic simulations detects such inverse Hall-Petch relation only for nanocrystalline materials. The main outcomes of present work are the described plasticity model and the conclusions that the ultrafine-grained metals (with grains of about 100-200 nm in diameter) has to have maximal dynamic shear strength and it is the most persistent to dynamic spall fracture because of maximal energy dissipation in it.
ISSN:0965-0393
1361-651X
DOI:10.1088/0965-0393/24/2/025013