Two mechanisms are studied to explain the asymmetrical chromiumdepletions observed ahead of SCC crack tips in nickel-base alloys:diffusion-induced grain boundary migration (DIGM) and plasticity-enhanced diffusion.On the one hand, DIGM is evidenced in a model Alloy 600 by focused ionbeam (FIB) coupled with scanning electron microscopy (SEM) cross-sectionimaging and analytical transmission electron microscopy (TEM) after annealing at500 °C under vacuum and at 340 °C after exposure to primary water. The occurrenceof grain boundary migration depends on the grain boundary character andmisorientation. On the other hand, the effect of plasticity on chromium diffusion innickel single-crystals is investigated by performing diffusion tests during creep testsat 500 and 350 °C. An enhancement of Cr diffusion is observed and a linearrelationship between the diffusion coefficient and strain rate is evidenced. At last, in an attempt to discriminate the two mechanisms, an analytical modeling of theCr-depleted areas observed at propagating SCC crack tips is proposed.