Size-dependent strain rate sensitivity in structural steel investigated using continuous stiffness measurement nanoindentation

The main purpose of this study is to characterize the size-dependent strain rate sensitivity in structural steel using the continue stiffness measurement (CSM) indentation. A series of experiments, such as CSM indentation , optical microscope examination, has been performed at the room temperature at different rate conditions. The results indicated that indentation hardness, strain rate , flow stress showed size-dependent behavior. The dependency of indentation hardness, strain rate, and flow stress on the indentation size was attributed to the transition of the dislocation nucleation rate and the dislocation behaviors during the indentation process. Since both hardness and strain rate showed the size-dependent behavior, SRS tended to depend on the indentation depth. The results indicated that the SRS was quite high over 2.0 at the indentation depth of 240 nm and quickly dropping to 0.08, finally around 0.046 at large indents. The SRS values at large indentations strongly agree with the general range reported for several types of low-carbon steel in the literature (Chatfield and Rote 1974, Nguyen et al. 2018b, Luecke et al. 2005). The results from the present study can be used in both static and dynamic analyses of structures as well as to assess and understand the deformation mechanism and the stress-state of material underneath the indenter tip during the process of the indentation testing.

Automated summary

The study aims to investigate the size-dependent strain rate sensitivity in structural steel using the continuous stiffness measurement (CSM) indentation method. Experimental results showed size-dependent behavior in indentation hardness, strain rate, and flow stress. The dependence on indentation size can be attributed to the transition of dislocation nucleation rate and dislocation behaviors during indentation. The findings can be used in structural analysis, deformation mechanism understanding, and stress-state assessment during indentation testing.