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Crystallographic effects on transgranular chloride-induced stress corrosion crack propagation of arc welded austenitic stainless steel

Haozheng J. Qu, Fei Tao, Nianju Gu, Timothy Montoya, Jason M. Taylor, Rebecca Schaller, Eric John Schindelholz, Janelle P. Wharry

2022npj Materials Degradation22 citationsDOIOpen Access PDF

Abstract

Abstract The effect of crystallography on transgranular chloride-induced stress corrosion cracking (TGCISCC) of arc welded 304L austenitic stainless steel is studied on >300 grains along crack paths. Schmid and Taylor factor mismatches across grain boundaries (GBs) reveal that cracks propagate either from a hard to soft grain, which can be explained merely by mechanical arguments, or soft to hard grain. In the latter case, finite element analysis reveals that TGCISCC will arrest at GBs without sufficient mechanical stress, favorable crystallographic orientations, or crack tip corrosion. GB type does not play a significant role in determining TGCISCC cracking behavior nor susceptibility. TGCISCC crack behaviors at GBs are discussed in the context of the competition between mechanical, crystallographic, and corrosion factors.

Topics & Concepts

Materials scienceMetallurgyStress corrosion crackingAustenitic stainless steelCorrosionWeldingGrain boundaryIntergranular corrosionContext (archaeology)Arc (geometry)CrackingChlorideFracture mechanicsAusteniteStress (linguistics)Composite materialMicrostructureGeometryGeologyPaleontologyPhilosophyMathematicsLinguisticsHydrogen embrittlement and corrosion behaviors in metalsCorrosion Behavior and InhibitionMicrostructure and Mechanical Properties of Steels
Crystallographic effects on transgranular chloride-induced stress corrosion crack propagation of arc welded austenitic stainless steel | Litcius