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In-situ neutron imaging of delayed crack propagation of high strength martensitic steel under hydrogen embrittlement conditions

David Lindblom, Armin E. Halilović, Robin Woracek, Alessandro Tengattini, Lukas Helfen, Carl F.O. Dahlberg

2024Materials Science and Engineering A10 citationsDOIOpen Access PDF

Abstract

This paper presents an in-situ observation, using neutron imaging, of delayed crack propagation in a high-strength martensitic steel specimen. Delayed cracking is believed to be caused by hydrogen embrittlement occurring due to the slow diffusion and accumulation of hydrogen ahead of a crack front, causing decreased ductility and eventual cracking under constant load. The experiment involved mechanical loading of a single-edge-notch bend specimen while submerged in an electrolyte solution (H2O + 3.5% NaCl) under cathodic polarization to facilitate hydrogen ingress. Intermittent crack propagation was observed for 12 h after the environment had been removed. The stress state at each crack configuration was extracted from a three-dimensional elastic–plastic finite element simulation, which was tailored to match the quantitative information acquired from the neutron radiographs of the fracture process. To gain insight into the evolution of hydrogen concentration with crack propagation, a modeling scheme for stress-assisted hydrogen diffusion was also employed.

Topics & Concepts

Materials scienceHydrogen embrittlementFracture mechanicsNeutron imagingHydrogenEmbrittlementMartensitic stainless steelMartensiteCrackingDuctility (Earth science)Composite materialMetallurgyNeutronCreepMicrostructureCorrosionOrganic chemistryChemistryPhysicsQuantum mechanicsHydrogen embrittlement and corrosion behaviors in metalsNuclear Physics and ApplicationsNuclear Materials and Properties
In-situ neutron imaging of delayed crack propagation of high strength martensitic steel under hydrogen embrittlement conditions | Litcius