Baker, Kristopher LearionWarner, D.H.2014-11-262014-11-262014-11-26201410.1016/j.engfracmech.2013.10.019https://infoscience.epfl.ch/handle/20.500.14299/109081Despite decades of study, the atomic-scale mechanisms of fatigue crack growth remain elusive. Here we use the coupled atomistic–discrete dislocation method, a multiscale simulation method, to examine the influence of dislocation glide resistance on near-threshold fatigue crack growth in an aluminum alloy. The simulations indicate that the threshold increases with an increase in dislocation glide resistance, and that a transition in the crack growth direction can occur when dislocation nucleation is inhibited by other nucleated dislocations. Three main mechanisms of fatigue crack propagation are observed: cleavage along the primary slip plane, crack extension by dislocation emission, and crack extension by opening along lattice defects.Threshold fatigueAluminum alloyMultiscale simulationcrack growth mechanismstext::journal::journal article::research article