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Segregation-induced grain-boundary precipitation during early stages of liquid-metal embrittlement of an advanced high-strength steel

Yuki Ikeda, Hsu-Chih Ni, A. Chakraborty, Hassan Ghassemi-Armaki, Jian‐Min Zuo, Reza Darvishi Kamachali, R. Maaß

2023Acta Materialia27 citationsDOIOpen Access PDF

Abstract

Liquid-metal embrittlement (LME) of galvanized (Zn-coated) advanced high-strength steels is a long-known problem in materials science. Here we reveal the initial microstructural processes underneath the Zn-coating that lead to LME-microcrack initiation in the steel substrate. We track the microstructural evolution during the first tens of milliseconds and find pronounced signatures of Fe-Zn intermetallic precipitation in both ferrite grain boundaries and at internal ferrite-oxide phase boundaries. In concert with novel CALPHAD-integrated density-based thermodynamic modelling, we demonstrate that Zn-rich intermetallic phase-nucleation can occur at markedly low processing temperatures due to a segregation transition. We show that a small Zn-enrichment caused by Zn bulk-diffusion during the initial temperature rise in a joining process is sufficient to induce the segregation transition and subsequent nucleation of Fe-Zn intermetallic grain-boundary phases, which the experiments link to crack initiation sites. These findings direct focus onto LME-controlling microstructural and thermodynamic phenomena at temperatures below the ductility trough and the austenite formation temperature.

Topics & Concepts

Materials scienceIntermetallicGrain boundaryMetallurgyNucleationEmbrittlementLiquid metal embrittlementCALPHADPrecipitationGalvanizationAusteniteOxidePhase (matter)MicrostructureComposite materialAlloyPhase diagramThermodynamicsLayer (electronics)ChemistryPhysicsOrganic chemistryMeteorologyMicrostructure and Mechanical Properties of SteelsHydrogen embrittlement and corrosion behaviors in metalsHigh Temperature Alloys and Creep
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