On the atomic solute diffusional mechanisms during compressive creep deformation of a Co-Al-W-Ta single crystal superalloy

We investigated the solute diffusional behavior active during compressive creep deformation at 150 MPa / 975 degrees C of a Co-Al-W-Ta single crystal superalloy in the [001] orientation. We report the formation of shear-bands that involves re-orientation of gamma/gamma' rafts to {111} from {001} planes, referring to as gamma/gamma' raft-rotation. In the shear-band regions, we observed abundant micro-twins, stacking faults (SFs), disordered zones within the gamma' termed as 'gamma pockets' and also few geometrically-close-packed (GCP) phases. We used a correlative approach blending electron microscopy and atom probe tomography to characterize the structure and composition of these features. The SFs were identified as intrinsic and exhibit a W enrichment up to 14.5 at.% and an Al deficiency down to 5.1 at.%, with respect to the surrounding gamma' phase. The micro-twin boundaries show a solute enrichment similar to the SFs with a distinct W compositional profile gradients perpendicular from the boundaries into the twin interior, indicating solute diffusion within the micro-twins. The gamma-pockets have a composition close to that of gamma but richer in W/Ta. Based on these observations, we propose (i) a solute diffusion mechanism taking place during micro-twinning, (ii) a mechanism for the gamma/gamma' raft-rotation process and evaluate their influence on the overall creep deformation of the present Co-based superalloy. (C) 2019 Acta Materialia Inc. Published by Elsevier Ltd. All rights reserved.