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Cr Segregation and Impact Fracture in a Martensitic Stainless Steel

Eleonora Bolli, Alessandra Fava, Paolo Ferro, S. Kačiulis, Alessio Mezzi, Roberto Montanari, Alessandra Varone

2020Coatings28 citationsDOIOpen Access PDF

Abstract

The fracture surfaces of a 10.5 wt.% Cr martensitic stainless steel broken in Charpy tests have been investigated through X-ray photoelectron spectroscopy (XPS). The specimens have been examined in two different conditions: as-quenched and heat treated for 10 h at 700 °C. The trends of Fe/Cr ratio vs. test temperature are similar to the sigmoidal curves of absorbed energy and, after both ductile and quasi-cleavage brittle fractures, such ratio is always significantly lower than the nominal value of the steel chemical composition. Cr segregation does not occur on a macroscopic scale but takes place in microscopic zones which represent weaker spots in the steel matrix and a preferred path for moving cracks. Small area (diameter 300 µm) XPS measurements evidenced a higher density of such microscopic zones in the inner part of probes; this is explained by the different diffusion length of Cr atoms in the external and inner parts during quenching from austenitic field which has been calculated through FEM simulations. No significant differences of Cr concentration were observed in fracture surfaces of probes with and without heat treatment. The results highlight how Cr segregation plays a role not only in the intergranular mode of fracture but also in the quasi-cleavage and ductile ones.

Topics & Concepts

Charpy impact testMaterials scienceCleavage (geology)MartensiteX-ray photoelectron spectroscopyIntergranular fractureQuenching (fluorescence)Intergranular corrosionAusteniteMetallurgyMartensitic stainless steelFracture (geology)BrittlenessComposite materialMicrostructureNuclear magnetic resonancePhysicsFluorescenceQuantum mechanicsMicrostructure and Mechanical Properties of SteelsHydrogen embrittlement and corrosion behaviors in metalsHigh Temperature Alloys and Creep