On the mechanism of fatigue crack initiation in high-angle grain boundaries

Fatigue crack initiation in high-angle grain boundaries is often observed experimentally, however, its mechanism is a subject of controversy. Low cycle fatigue loading has been applied to super-austenitic stainless steel Sanicro 25 and surface features developed during cyclic loading with high strain amplitudes were studied and analyzed using SEM, EBSD and FIB cuts. Dense array of persistent slip markings developed on the surface of grains was found. Extrusions and intrusions emerged not only in the direction of the surface but also normal to the grain boundaries. Growing extrusions were bent and started to push two neighbor grains locally apart leading to production of void-like discontinuities. Deepening intrusions produced void-like defects or microcracks on the grain boundary. Both these processes led to the substantial weakening of the grain boundary. Coalescence of void-like discontinuities and microcracks on the grain boundary during cyclic loading led to the production of the grain boundary crack. Presented and discussed experimental findings lead to novel mechanism of high-angle grain boundary crack initiation and raise serious doubts about the theories of brittle-like origin of grain boundary cracks.

Automated summary

Studies have shown that the mechanism of fatigue crack initiation in high-angle grain boundaries is controversial. In this research, experiments were conducted on super-austenitic stainless steel Sanicro 25 to study the surface features that developed during cyclic loading with high strain amplitudes. The results revealed the presence of slip markings on the surface of grains, as well as extrusions and intrusions along the surface and normal to the grain boundaries. These processes ultimately weakened the grain boundary and led to the production of grain boundary cracks. These experimental findings challenge the theories suggesting a brittle-like origin of grain boundary cracks.