Dislocation interactions and crack nucleation in a fatigued near-alpha titanium alloy

Abstract Dislocation interactions at the crack nucleation site were investigated in near-alpha titanium alloy Ti-6242Si subjected to low cycle fatigue. Cyclic plastic strain in the alloy resulted in dislocation pile-ups in the primary alpha grains, nucleated at the boundaries between the primary alpha and the two-phase regions. These two phase regions provided a barrier to slip transfer between primary alpha grains. We suggest that crack nucleation occurred near the basal plane of primary alpha grains by the subsurface double-ended pile-up mechanism first conceived by Tanaka and Mura. Superjogs on the basal 〈 a 〉 dislocations were observed near the crack nucleation location. The two phase regions showed direct transmission of a 3 dislocations between secondary alpha plates, transmitted through the beta ligaments as a [ 010 ] , which then decompose into ( a / 2 ) 〈 111 〉 dislocation networks in the beta. The beta ligaments themselves do not appear to form an especially impenetrable barrier to slip, in agreement with the micropillar and crystal plasticity investigations of Zhang et al.