Add to ORKGWe 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
Crystal plasticity occurs by deformation bursts due to the avalanchelike motion of dislocations. Her...
The classical view of plasticity in metals assumed that any fluctuations in the underlying dislocati...
Three-dimensional discrete dislocation dynamics simulations are used to study strain-controlled plas...
We show that slowly sheared metallic nanocrystals deform via discrete strain bursts (slips), whose s...
Slowly compressed microcrystals deform via intermittent slip events, observed as displacement jumps ...
Directly tracing the spatiotemporal dynamics of intermittent plasticity at the micro- and nanoscale ...
The transition from elastic to plastic deformation in crystalline metals shares history dependence a...
In small-scale metallic systems, collective dislocation activity has been correlated with size effec...
In small-scale metallic systems, collective dislocation activity has been correlated with size effec...
Nanoindentation techniques recently developed to measure the mechanical response of crystals under e...
Plastic deformation in crystalline materials consists of an ensemble of collective dislocation glide...
We present differences in the mechanical behavior of nanoscale gold and molybdenum single crystals. ...
Slowly-compressed single crystals, bulk metallic glasses (BMGs), rocks, granular materials, and the ...
Mechanical deformation of nanopillars displays features that are distinctly different from the bulk ...
We present differences in the mechanical behavior of nanoscale gold and molybdenum single crystals. ...
Crystal plasticity occurs by deformation bursts due to the avalanchelike motion of dislocations. Her...
The classical view of plasticity in metals assumed that any fluctuations in the underlying dislocati...
Three-dimensional discrete dislocation dynamics simulations are used to study strain-controlled plas...
We show that slowly sheared metallic nanocrystals deform via discrete strain bursts (slips), whose s...
Slowly compressed microcrystals deform via intermittent slip events, observed as displacement jumps ...
Directly tracing the spatiotemporal dynamics of intermittent plasticity at the micro- and nanoscale ...
The transition from elastic to plastic deformation in crystalline metals shares history dependence a...
In small-scale metallic systems, collective dislocation activity has been correlated with size effec...
In small-scale metallic systems, collective dislocation activity has been correlated with size effec...
Nanoindentation techniques recently developed to measure the mechanical response of crystals under e...
Plastic deformation in crystalline materials consists of an ensemble of collective dislocation glide...
We present differences in the mechanical behavior of nanoscale gold and molybdenum single crystals. ...
Slowly-compressed single crystals, bulk metallic glasses (BMGs), rocks, granular materials, and the ...
Mechanical deformation of nanopillars displays features that are distinctly different from the bulk ...
We present differences in the mechanical behavior of nanoscale gold and molybdenum single crystals. ...
Crystal plasticity occurs by deformation bursts due to the avalanchelike motion of dislocations. Her...
The classical view of plasticity in metals assumed that any fluctuations in the underlying dislocati...
Three-dimensional discrete dislocation dynamics simulations are used to study strain-controlled plas...