Litcius/Paper detail

Oxidation Behavior and Outward Diffusion of Al Along Oxide Grain Boundaries of FeCrAl Alloys Overdoped with Zr and Hf

Samer I. Daradkeh, Oscar Recalde, Marwan S. Mousa, Dinara Sobola, Torben Boll

2023High Temperature Corrosion of Materials9 citationsDOIOpen Access PDF

Abstract

Abstract The formation of the α-Al 2 O 3 scale on reactive element (RE)-doped FeCrAl alloys is commonly believed to be primarily caused by inward oxygen transport along grain boundaries. However, this study suggests that metal ion outward diffusion also plays a role in the development of the oxide scales and their microstructural characteristics. The study examines the oxidation behavior and grain boundary outward diffusion of iron-chromium alloys containing ~ 10 at% aluminum and ~ 22 at% chromium, doped with an over-critical concentration of REs, i.e., Zr and Hf. All samples were investigated after thermal exposure at 1100 °C by scanning electron microscopy (SEM), transmission electron microscopy (TEM), and atom probe tomography (APT). As a result of the overdoping, a considerable increase in oxide growth, an increase in the depth of internal oxidation, and RE-oxide formation near and at oxide grain boundaries (GBs) were observed as a consequence of increased inward and outward diffusion. The effect of overdoping manifests itself differently depending on the RE type and amount due to different solubility, ionic size, and electronic structure of alumina. The sample with Zr retained the adhesion of alumina to the alloy after the first and second thermal exposure, while Hf overdoping resulted in severe spallation after the second thermal exposure.

Topics & Concepts

Grain boundaryOxideMaterials scienceDiffusionAlloyTransmission electron microscopyAtom probeScanning electron microscopeMetallurgyIonic bondingDopingInternal oxidationMicrostructureIonChemistryComposite materialNanotechnologyThermodynamicsPhysicsOptoelectronicsOrganic chemistryHigh-Temperature Coating BehaviorsNuclear Materials and PropertiesMetallurgical Processes and Thermodynamics