Quasi-cleavage hydrogen-assisted cracking path investigation by fractographic and side surface observations

•Quasi-cleavage hydrogen-assisted cracking path is mainly determined by local stress fields.•Quasi-cleavage cracks can significantly deviate from specific crystallographic planes.•Nano-sized voids are found in the quasi-cleavage cracks tips.•In-situ hydrogen charging is more suitable for the investi...

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Bibliographic Details
Published in:Engineering fracture mechanics 2019-06, Vol.214, p.177-193
Main Authors: Merson, E.D., Myagkikh, P.N., Poluyanov, V.A., Merson, D.L., Vinogradov, A.
Format: Article
Language:English
Subjects:
Charging
Cleavage
Coalescing
Crack tips
Crystallography
Ductile fracture
Ductile-brittle transition
Electron backscatter diffraction
Environmentally assisted cracking
Fracture mechanics
Fracture surfaces
Heat treating
Hydrogen
Hydrogen embrittlement
Low carbon steels
Microscopy
Scanning electron microscopy
Scanning microscopy
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Summary:•Quasi-cleavage hydrogen-assisted cracking path is mainly determined by local stress fields.•Quasi-cleavage cracks can significantly deviate from specific crystallographic planes.•Nano-sized voids are found in the quasi-cleavage cracks tips.•In-situ hydrogen charging is more suitable for the investigation of hydrogen-assisted cracking. Despite recent substantial advances in understanding of hydrogen embrittlement (HE), many important aspects of this widespread phenomenon remain a subject of debates. Particularly, remarkably different opinions have been expressed on the nature of hydrogen-assisted cracking (HAC), which produces quasi-cleavage (QC) fracture surfaces in iron and low-carbon steels. Basically, two conflicting groups of theories are distinguished concerning causes the QC phenomenon: brittle cleavage-like models and ductile models exploiting localized ductile micro- or nanovoid concepts at the core. The present study was aimed at gaining a new insight into the QC mechanism through the detailed investigation of the HAC path by the microscopic observations of the side and fracture surfaces of the annealed low-carbon steel, which was tensile tested in the ex- and in-situ cathodic hydrogen charged conditions. Using a combination of the scanning electron microscopy, confocal laser scanning microscopy and electron-backscattering diffraction, it was found that the in-situ charging is more suitable for the investigation of HAC by side surface observations because it provokes QC cracking on the side surface and suppresses normal ductile fracture. As opposes to this, HAC after ex-situ charging occurs mainly internally. In this condition, HAC interferes with the normal ductile fracture on the side surface. It is established that the path of secondary QC cracks in the in-situ charged specimen is determined predominantly by the local stress distributions. This holds even on the scale of individual grain. Large deviations of the quasi-cleavage cracks paths from the specific crystallographic planes are found and explained. Nano-voids are regularly observed at the crack tips. Thus, the nano-voids coalescence is supposed to be an integral part of QC HAC.
ISSN:0013-7944
1873-7315
DOI:10.1016/j.engfracmech.2019.04.042