[en] After a presentation of the industrial context and of some knowledge about stress corrosion cracking (SCC) of 5xxx alloys (notably their sensitivity to intergranular dissolution in presence of the Al₃Mg₂ phase in grain boundaries) and about other mechanisms intervening in SCC, this research thesis reports a characterization of intergranular precipitation in the alloys for which SCC and corrosion fatigue tests have been performed. Experimental results are reported and discussed (crack initiation and growth, growth rate, loading mode). The simulation of a model microstructure at the atomic scale is presented. It allows hydrogen trapping to be studied with respect to the presence of magnesium at the grain boundary. A numerical model of the Al-Mg system is developed to study the first stages of magnesium-rich intergranular precipitation. The next part reports the study of hydrogen intergranular trapping in Al-Mg by focusing on the Mg-H binding energy and on trapping occurring in the boundary. In conclusion, the author proposes a fracture mechanism at the atomic scale