Preferred corrosion pathways for oxygen in Al2Ca-twin boundaries and dislocations

TL;DR

This study reveals that oxygen diffuses preferentially along crystal defects in Al2Ca, causing amorphous oxide formation and structural changes, which are crucial for understanding oxidation in intermetallic materials.

Contribution

It provides the first detailed atomic-scale characterization of oxygen-induced amorphous oxide formation at defects in Al2Ca Laves phase.

Findings

Oxygen enhances diffusion along dislocations and twin boundaries.

Amorphous Al2O3 forms at defects, replacing original structures.

Oxygen-induced phases are enriched in oxygen and alter defect structures.

Abstract

With an ongoing discussion on the oxygen diffusion along crystal defects remaining, it is difficult to study this phenomenon in Al containing intermetallic materials due to its rapid and passivating oxide formation. We report here the observation of enhanced oxygen diffusion along crystal defects, i.e. dislocations and twin boundaries, in the C15 Al 2 Ca Laves phase and how the presence of oxygen induces structural changes at these defects. Three main phases were identified and characterized structurally by aberration-corrected, atomic resolution scanning transmission electron microscopy, analytically by energy dispersive X-ray spectroscopy and electron energy loss spectroscopy. Unlike the C15 bulk phase, the twin boundary and dislocation transformed into a few nanometer wide amorphous phase, which depletes in Al and Ca but is highly enriched in oxygen. The dislocation even shows coexistence of the amorphous phase with a simple Al-rich A1 fcc phase. This A1 phase only depletes in Ca, not in Al (Al remains at bulk concentration), and is also enriched in oxygen. The Al-rich A1 phase is coherent with the C15 matrix. Electron energy loss spectroscopy revealed the amorphous phase to be Al 2 O 3 . We thereby show as one of the first studies that oxygen diffusion along crystal defects, especially also at the twin boundary can induce the formation of an amorphous oxide along themselves. The identification of oxygen-induced transformation at strained defects has to be considered when the material is exposed to air during plastic deformation at elevated temperatures.