Abstract
Twin-thickness-controlled plastic deformation mechanisms are well understood for submicron-sized twin-structural polycrystalline metals. However, for twin-structural nanocrystalline metals where both the grain size and twin thickness reach the nanometre scale, how these metals accommodate plastic deformation remains unclear. Here, we report an integrated grain size and twin thickness effect on the deformation mode of twin-structural nanocrystalline platinum. Above a ∼10 nm grain size, there is a critical value of twin thickness at which the full dislocation intersecting with the twin plane switches to a deformation mode that results in a partial dislocation parallel to the twin planes. This critical twin thickness value varies from ∼6 to 10 nm and is grain size-dependent. For grain sizes between ∼10 to 6 nm, only partial dislocation parallel to twin planes is observed. When the grain size falls below 6 nm, the plasticity switches to grain boundary-mediated plasticity, in contrast with previous studies, suggesting that the plasticity in twin-structural nanocrystalline metals is governed by partial dislocation activities.
Highlights
Twin-thickness-controlled plastic deformation mechanisms are well understood for submicron-sized twin-structural polycrystalline metals
The deformation mechanisms of twin-structural coarse-grained[1,2] and submicrometre sized polycrystalline metals[1,2,4,5,7,8,9,10,11,12,13,14] have been extensively studied by transmission electron microscopy (TEM), which has revealed that the twin boundaries (TBs) are more stable against sliding or diffusion than conventional grain boundaries (GBs) but can obstruct the partial dislocation that glides on the plane that is inclined to the TBs, making twin-structural metals very successful in terms of strength
Most grains with a d ranging between 4 and 30 nm are separated by high-angle GBs, and many grains contain growth twins with a twin thickness (TT) ranging from ∼1 to 15 nm
Summary
Twin-thickness-controlled plastic deformation mechanisms are well understood for submicron-sized twin-structural polycrystalline metals. For a TT below this point, partial dislocations glide on the {111} planes that are parallel to the TBs, leading to softening This mechanism has been supported by many other classic MD simulations[16,18,19,20,21,22,23,24,25] and promotes the widespread belief that the strengthening/softening of twinstructural NC metals is governed by partial dislocation behaviours, full dislocations and GB-mediated plasticity (softening deformation model), even though they are rarely observed in experiments. In this study, using a homemade double-tilt high-resolution (HR) TEM tensile stage[30,31], the plastic deformation mechanism of twin-structural NC Pt thin films are investigated in situ at the atomic scale We discover that both the grain size and TT can significantly impact the deformation model, and some of the deformation mechanisms a not observed in twin-structural NC metals
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