Microscopic mechanism of the L1_2–D0_19 phase transformation in a Co-base single crystal superalloy

This record contains datasets related to the publication: N. Karpstein et al., Microscopic mechanism of the L12-D019 phase transformation in a Co-base single crystal superalloy, Acta Materialia (2024), doi:10.1016/j.actamat.2024.120416. A readme file containing descriptions of datatypes can be found...

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Main Authors: Karpstein, Nicolas, Spiecker, Erdmann
Format: Dataset
Language:English
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Summary:This record contains datasets related to the publication: N. Karpstein et al., Microscopic mechanism of the L12-D019 phase transformation in a Co-base single crystal superalloy, Acta Materialia (2024), doi:10.1016/j.actamat.2024.120416. A readme file containing descriptions of datatypes can be found in the main folder.   Abstract: In γ′-strengthened superalloys based on the Co-Al-W system, the stability of the γ′ phase is often limited, as it is found to transform into other phases such as B2 and D019 after long-term annealing. To explore the details behind the annealing-induced transformation from the metastable L12-γ′ phase to the thermodynamically stable D019-χ phase in the single-crystalline Co-base superalloy ERBOCo-VF60 (Co79.8Al8.9W9.0Ta2.3 in at.%), scanning transmission electron microscopy and atom probe tomography are employed. Due to the structural similarity between the L12 and D019 structures, coherent plate-shaped χ precipitates are formed in the γ/γ′ microstructure parallel to {111} planes through a shear-based transformation mechanism. While the χ phase precipitates slowly during isothermal aging, its formation can be significantly accelerated locally by coating the superalloy with a Cr-rich layer, which indirectly stabilizes the χ phase as revealed by thermodynamic calculations. This procedure allowed us to obtain an intermediate (incomplete) state of χ-phase formation in terms of both crystal structure and composition. By characterizing the partial dislocations at the tip of growing χ precipitates, the microscopic details of the shear-based cubic-to-hexagonal transformation from L12 to D019 are uncovered. The compositional aspect of the transformation involves a significant diffusion-mediated enrichment of W in the χ phase, accompanied by a simultaneous W depletion in the γ′ phase, leading to its transformation to the γ phase.
ISSN:1873-2453
DOI:10.5281/zenodo.13325200