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Statistics of dislocation slip avalanches in nanosized single crystals show tuned critical behavior predicted by a simple mean field model.
Nir Friedman
1 ,
Andrew T Jennings ,
Georgios Tsekenis ,
Ju-Young Kim ,
Molei Tao ,
Jonathan T Uhl ,
Julia R Greer ,
Karin A Dahmen
Aug 31 2012
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Abstract
We show that slowly sheared metallic nanocrystals deform via discrete strain bursts (slips), whose size distributions follow power laws with stress-dependent cutoffs. We show for the first time that plasticity reflects tuned criticality, by collapsing the stress-dependent slip-size distributions onto a predicted scaling function. Both power-law exponents and scaling function agree with mean-field theory predictions. Our study of 7 materials and 2 crystal structures, at various deformation rates, stresses, and crystal sizes down to 75 nm, attests to the universal characteristics of plasticity.