Abstract
In this investigation, a model predicting toughness anisotropy in textured ceramics containing elongated grains and in composites reinforced with rod‐shaped particles is presented. The model predictions are based on the assumption that crack deflection is the only toughening mechanism. In the model, toughness anisotropy is calculated as a function of texture degree. For composite materials, the volume fraction of the reinforcement phase is also an input parameter. Correspondence between model and experiment was established by comparing measured toughness anisotropies in β‐Si3N4 and Al2O3/SiC whisker composites to model predictions. In these model predictions, measured orientation distributions from hot‐pressed and hot‐forged specimens were employed. The potential for relating other toughening mechanisms in a similar format is also addressed, since the model and experimental measurements give different results. The crack deflection model simultaneously overpredicts the toughening enhancement and underpredicts the toughening anisotropy observed in the experiments.
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