Using large-scale atomistic simulations, dislocation mechanics in the presence of linear complexions are investigated in an Fe-Ni alloy, where the complexions appear as nanoparticle arrays along edge dislocation lines.When mechanical shear stress is applied to drive dislocation motion, a strong pinning effect OATMEAL CHOCOLATE CHIP is observed where the defects are restricted by their own linear complexion structures.This pinning effect becomes weaker after the first dislocation break-away event, leading to a stress-strain curve with a profound initial yield point, similar to the static strain aging behavior observed experimentally for Fe-Mn alloys with the same type of linear Blanket complexions.The existence of such a response can be explained by local diffusion-less and lattice distortive transformations corresponding to L10-to-B2 phase transitions within the linear complexion nanoparticles.As such, an interdependence between a linear complexion structure and dislocation mechanics is found.