Thickness-Dependent Strain Rate Sensitivity of Nanolayers via the Nanoindentation Technique

Abstract: Abstract:The strain rate sensitivity (SRS) and dislocation activation volume are two inter-related material properties for understanding thermally-activated plastic deformation, such as creep. For face-centered-cubic metals, SRS normally increases with decreasing grain size, whereas the opposite holds for body-center-cubic metals. However, these findings are applicable to metals with average grain sizes greater than tens of nanometers. Recent studies on mechanical behaviors presented distinct deformation mecha… Show more

“…It has a similar conclusion to the hardness change with individual layer thickness under CSM test. As for the metals with large grain sizes (larger than tens of nanometers), the SRS of face-center-cubic (fcc) metals usually increases as the grain size decreases, while bodycenter-cubic (bcc) metals have the opposite behavior [48]. The current result manifests that the SRS behavior of the Mg/Ti (hcp/hcp) system is similar to the body-center-cubic (bcc) metals as the grain size changes.…”

Revealing thickness dependence of hardness, strain rate sensitivity, and creep resistance of nano-crystalline magnesium/titanium multilayers by nanoindentation

“…It has a similar conclusion to the hardness change with individual layer thickness under CSM test. As for the metals with large grain sizes (larger than tens of nanometers), the SRS of face-center-cubic (fcc) metals usually increases as the grain size decreases, while bodycenter-cubic (bcc) metals have the opposite behavior [48]. The current result manifests that the SRS behavior of the Mg/Ti (hcp/hcp) system is similar to the body-center-cubic (bcc) metals as the grain size changes.…”

Revealing thickness dependence of hardness, strain rate sensitivity, and creep resistance of nano-crystalline magnesium/titanium multilayers by nanoindentation

The effect of coherent interface on strain-rate sensitivity of highly textured Cu/Ni and Cu/V multilayers