Crack-tip Shielding by Dislocations and Fracture Toughness in NaCl Crystals

Abstract

Stress modification by dislocations around a crack tip and its effect on fracture toughness in NaCl crystals were investigated using a photoelastic method. NaCl crystals are very brittle and give small values of fracture toughness K_IC at and below room temperature. The crystals become fairly ductile to deform over 50% in elongation and their apparent K_IC values are markedly increased at elevated temperatures. In crystals once stretched at elevated temperatures, the K_IC values are evidently increased even at 77 K through a stress modification due to the presence of dislocations around a crack tip. The stress modification by dislocations is actually revealed in photoelastic images. A compressive stress field appears near the crack tip when an external load is removed after the introduction of dislocations. The strength of the compressive stress field, |k_D|, estimated from a photoelastic image is nearly equal to the increment of K_IC values due to dislocations at 77 K. The slip operation on both {110} and {001} planes, which provides five independent slip systems, takes place around a crack tip at elevated temperatures. The slip operation on {110} planes alone providing two independent slip systems is observed even at room temperature where K_IC values are very small. It is thus evident that the formation of strong K_D fields takes place through the operation of a sufficient number of independent slip systems for increasing K_IC