Heterogeneous local plastic deformation of interstitial free steel revealed using in-situ tensile testing and high angular resolution electron backscatter diffraction

TL;DR

This study uses in-situ tensile testing and high-resolution EBSD to investigate how interstitial free steel deforms locally, revealing the microstructural mechanisms behind strain localization and flow patterning.

Contribution

It demonstrates the correlation between dislocation storage and deformation patterns in IF steel, providing insights for improving steel processing and micromechanical modeling.

Findings

Flow localization is linked to dislocation storage differences.

Homogeneous flow shows FCC-like deformation patterns.

In-situ tests reveal development of dislocation fields during deformation.

Abstract

Metals are important structural materials for transport and the built environment. Low carbon steels can fail through strain localisation due to the role of interstitial solute atoms (such as carbon and nitrogen) interacting with mobile dislocations, and this gives rise to the Portevin-Le Chatelier effect and the formation of Luders bands. In this work, we use in-situ tensile testing and observation with High Angular Resolution Electron Back Scatter Diffraction (HR-EBSD) to explore deformation patterning in two Interstitial Free (IF) steel samples. One of these steels was heat treated to trigger strain localisation and Luders bands whilst the other was heat treated to homogenise plastic strain and limit flow localisation. Our work reveals that flow localisation at the macroscopic scale is closely correlated with differences in the storage of dislocations at the microscale through analysis of the HR-EBSD derived fields of stored Geometrically Necessary Dislocations (GNDs). Homogeneous plastic flow correlates with more 'Face Centred Cubic (FCC)-like' deformation patterning in these Body Centred Cubic (BCC) materials, where work hardening is correlated with the association of dislocation networks which interact with triple junctions and grain boundaries, and our in-situ tests enable us to see how these fields develop. Our findings enable the modification of steel processing routes, and micromechanical models, based upon information obtained from these in-situ tests.