Textural, Microstructural and Chemical Characterization of Ferritic Stainless Steel Affected by the Gold Dust Defect
Beatriz Amaya Dolores,
Andrés Ruiz Flores,
Andrés Núñez Galindo,
José Juan Calvino Gámez,
Juan F. Almagro,
Luc Lajaunie
Affiliations
Beatriz Amaya Dolores
Laboratory & Research Section, Technical Department, Acerinox Europa S.A.U., 11379 Palmones, Spain
Andrés Ruiz Flores
Laboratory & Research Section, Technical Department, Acerinox Europa S.A.U., 11379 Palmones, Spain
Andrés Núñez Galindo
Laboratory & Research Section, Technical Department, Acerinox Europa S.A.U., 11379 Palmones, Spain
José Juan Calvino Gámez
Department of Materials Science and Metallurgical Engineering and Inorganic Chemistry, IMEYMAT, Faculty of Science, University of Cadiz, 11510 Puerto Real, Spain
Juan F. Almagro
Laboratory & Research Section, Technical Department, Acerinox Europa S.A.U., 11379 Palmones, Spain
Luc Lajaunie
Department of Materials Science and Metallurgical Engineering and Inorganic Chemistry, IMEYMAT, Faculty of Science, University of Cadiz, 11510 Puerto Real, Spain
The “gold dust defect” (GDD) appears at the surface of ferritic stainless steels (FSS) and degrades their appearance. Previous research showed that this defect might be related to intergranular corrosion and that the addition of aluminium improves surface quality. However, the nature and origin of this defect are not properly understood yet. In this study, we performed detailed electron backscatter diffraction analyses and advanced monochromated electron energy-loss spectroscopy experiments combined with machine-learning analyses in order to extract a wealth of information on the GDD. Our results show that the GDD leads to strong textural, chemical, and microstructural heterogeneities. In particular, the surface of affected samples presents an α-fibre texture which is characteristic of poorly recrystallised FSS. It is associated with a specific microstructure in which elongated grains are separated from the matrix by cracks. The edges of the cracks are rich in chromium oxides and MnCr2O4 spinel. In addition, the surface of the affected samples presents a heterogeneous passive layer, in contrast with the surface of unaffected samples, which shows a thicker and continuous passive layer. The quality of the passive layer is improved with the addition of aluminium, explaining the better resistance to the GDD.
