Abstract

Slow strain rate testing (SSRT) was used to study the effect of the microstructure on the stress corrosion cracking (SCC) susceptibility of Al–Mg alloy sheet containing 6.8 wt.% Mg. In the cold-rolled and fully annealed conditions, high SCC susceptibility was experienced. In those cases the ductility was strongly affected by the presence of corrosive environment (for hard temper: Elair=13.6%, ElSCC=0.6%; for annealed condition: Elair=24.1–25.3%, ElSCC=3.2–4.2%) and the elongation loss was great, Elloss=81.7–95.6%. It is supposed that the high SCC susceptibility results from a continuous network of the β-phase (Mg5Al8) precipitate at grain boundaries for the annealed temper, and heavy precipitation of β-phase along the planes of localized deformation for the hard temper. High SCC resistance attained after thermal exposure at the temperature range 225–285 °C (stabilized condition). The ductility was almost unaffected by the presence of corrosive environment (Elair=12.8–23.2%, ElSCC=12.8–22%) and the elongation loss was small, Elloss<7%. High SCC resistance was related to the stabilized structure, which causes discontinuous β-phase (Mg5Al8) precipitation in a globular form, uniformly distributed throughout the structure.