Effects of dislocations and hydrogen concentration on hydrogen embrittlement of austenitic 316 stainless steels

The effects of dislocations and hydrogen concentration on the hydrogen embrittlement (HE) in 316 austenitic stainless steels (316SS) were systematically investigated in the present study. The results revealed a decrease in tensile strength and ductility of 316SS after hydrogen charging. Furthermore, the severity of HE was dependent on the hydrogen concentration. The results of x-ray diffraction revealed the presence of martensite in the hydrogen-charged (50 mA/cm(2)) specimen annealed at 1000 degrees C. This was attributed to the internal stress originating from hydrogen-induced lattice expansion. The analysis of the fracture surface of all the specimens revealed an increase in the brittleness with the absorption of hydrogen. An increase in the hydrogen concentration induced a transformation of the fracture mode i.e., from ductile dimple fracture to cleavage and intergranular fractures. The evolution of hydrogen in 316SS was associated with the defects induced by deformation. The shift in the major desorption peaks of the annealed specimen to the high-temperature region indicated the formation of effective hydrogen-trapping sites during hydrogen-charging. The specimens were subjected to positron lifetime spectroscopy and thermal desorption spectroscopy. The results for the raw specimen, charged at 20 mA/cm(2), revealed the gradual escape of hydrogen atoms and recovery of vacancy defects with an increase in the annealing temperature. In addition, the hydrogen-induced and cold rolling-induced dislocations was preserved. (C) 2021 Elsevier B.V. All rights reserved.

Automated summary

The study systematically investigated the effects of dislocations and hydrogen concentration on hydrogen embrittlement in 316 austenitic stainless steels. The results showed a decrease in tensile strength and ductility of 316SS after hydrogen charging, with the severity of hydrogen embrittlement depending on hydrogen concentration. X-ray diffraction results revealed the presence of martensite in hydrogen-charged specimens, attributed to hydrogen-induced lattice expansion. Additionally, an increase in hydrogen concentration led to a transformation in fracture mode and the formation of effective hydrogen-trapping sites.