Assessment of slip transfer criteria for prismatic-to-prismatic slip in pure Ti from 3D grain boundary data

TL;DR

This study evaluates various criteria for predicting slip transfer across grain boundaries in pure Ti, demonstrating that certain geometric parameters like the angle  and Luster-Morris parameter m' most accurately predict slip transfer in prismatic slip.

Contribution

It introduces a novel application of LabDCT and 3D grain boundary data to assess slip transfer criteria, providing clearer insights into grain boundary influence on deformation.

Findings

Angle  and m' best predict slip transfer

Metrics based on twist angle  and LRB are less accurate

LabDCT enables detailed 3D grain boundary analysis

Abstract

Slip transfer and blocking across grain boundaries was studied in a Ti foil with a strong rolling texture deformed in tension. Prior to deformation, the shape of the grains and the orientation of the grain boundaries were quantified through laboratory scale diffraction contrast tomography (LabDCT). Mechanical deformation led to the activation of <a> prismatic slip, and slip transfer/blocking was assessed in > 300 grain boundaries by means of slip trace analysis and electron backscatter diffraction. A categorical model was employed to accurately assess slip transfer, and the "F1 score" of various slip transfer criteria proposed in the literature was evaluated for the first time from 3D grain boundary information. Remarkably, for the prismatic-dominated slip transfer in the current Ti sample, the results show that the best predictions of slip transfer/blocking are provided by the angle \k{appa}, which is directly related to the residual Burgers vector, and by the Luster-Morris parameter m'. In contrast, metrics based on the twist angle {\theta} and on the LRB criterion were not able to predict accurately slip transfer/blocking. Thus, the extensive analysis of the 3D grain boundary data and the novel application of LabDCT was able to help clarify the role of grain boundary orientation on the mechanisms of plastic deformation in polycrystals with strong prismatic-dominated slip.