Nucleation of nanocracks by a quasicleavage process in a dislocation-free zone

Abstract

The initiation and propagation of nanometre-scale cracks has been investigated in detail using dislocation modelling and in situ transmission electron microscopy (TEM) observations for the intermetallic compound Fe₃Al under mode I loading. A discrete dislocation model is proposed to assess quasistatic equilibrium, emission of dislocations from the crack tip and shielding of near-tip dislocations. The equilibrium location and number of dislocations are determined by a minimum-energy requirement. The in-situ TEM test revealed the following response. When cracks propagate directly from the thin edge of a double-jet hole, no dislocation is emitted from the crack tip. However. in thicker regions of the foils, a large number of dislocations are emitted from the crack tip, and a nanosized crack is formed in front of the crack tip region but not at the crack tip. A finite-element method-discrete dislocation calculation provides insight into how dislocation shielding leads to nanocrack nucleation. It also indicates the emergence of a tensile stress peak ahead of the crack tip, as the dislocations pile up in the front of crack tip. From TEM observation, the distances between discontinuous nanocracks and the main crack tip were in the range 4–100 nm, which is dependent on the applied loading, such that the distances increase with increasing applied stress intensity factor. A gigantic superdislocation and a minidislocation array are used to simulate the effect of grain boundary (or interface) on the peak stress at crack tip. It was found that grain boundary (or interface) controls the magnitude of the stress peak at the crack tip.