Hydrogen embrittlement through the formation of low-energy dislocation nanostructures in nanoprecipitation-strengthened steels
Peng Gong, John Nutter, Pedro E.J. Rivera-Díaz-del-Castillo, W.M. Rainforth
Abstract
Hydrogen embrittlement is shown to proceed through a previously unidentified mechanism. Upon ingress to the microstructure, hydrogen promotes the formation of low-energy dislocation nanostructures. These are characterized by cell patterns whose misorientation increases with strain, which concomitantly attracts further hydrogen up to a critical amount inducing failure. The appearance of the failure zone resembles the "fish eye" associated to inclusions as stress concentrators, a commonly accepted cause for failure. It is shown that the actual crack initiation is the dislocation nanostructure and its associated strain partitioning.
Topics & Concepts
MisorientationMaterials scienceHydrogen embrittlementDislocationMicrostructureNanostructureHydrogenEmbrittlementStrain (injury)Lamellar structureStrain energyComposite materialMetallurgyNanotechnologyGrain boundaryChemistryStructural engineeringBiologyAnatomyFinite element methodCorrosionEngineeringOrganic chemistryHydrogen embrittlement and corrosion behaviors in metalsNuclear Materials and PropertiesCorrosion Behavior and Inhibition