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Precipitation phenomena in impulse friction stir welded 2024 aluminium alloy

Iuliia Morozova, Aleksandra Królicka, Aleksei Obrosov, Yitong Yang, Nikolay Doynov, Sabine Weiß, Vesselin Michailov

2022Materials Science and Engineering A31 citationsDOIOpen Access PDF

Abstract

Microhardness variations across the friction stir welded (FSW) and impulse friction stir welded (IFSW) AA2024–T351 joints have been elucidated by the transformations of the S–Al2CuMg phase with a special focus on a distinguished hardness peak within the heat-affected zone (HAZ) of the impulse welds. The increase in hardness within the stir zone (SZ) originated from the partial re-precipitation of the initial Guinier–Preston-Bagaryatsky zones (GPB) and metastable S needles, previously dissolved.) Formation and growth of stable S precipitates via coalescence accounted for the softening through the thermo-mechanically affected zone (TMAZ). The peak strengthening within the HAZ of the IFSW joints was mainly caused by the dense needle-shaped S particles, which can be explained by a mutual influence of the process specific temperature and strain cycles. Dislocations and subgrain boundaries introduced to the material due to plastic deformation facilitated the nucleation of strengthening S precipitates in the HAZ. It demonstrates that the impact of deformation should be considered by the characterization of the precipitation development in the HAZ.

Topics & Concepts

Friction stir weldingMaterials scienceIndentation hardnessSofteningMetallurgyNucleationAlloyPrecipitationWeldingCoalescence (physics)Heat-affected zoneAluminium alloyAluminiumComposite materialMicrostructureThermodynamicsPhysicsAstrobiologyMeteorologyAdvanced Welding Techniques AnalysisAluminum Alloys Composites PropertiesAluminum Alloy Microstructure Properties
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