Microstructure and mechanical properties of SiC whisker reinforced ZrO2–6 mol.-%Y2O3 composites

Abstract

Microstructure, mechanical properties, fracture behaviour, and toughening mechanisms of hot pressed SiC whisker (SiC_w)

reinforced ZrO₂–6 mol.-%Y₂O₃ composites were investigated via transmission electron microscopy, scanning electron microscopy, X-ray diffraction, and mechanical testing. The experimental results show that there is a continuous increase in the Vickers hardness, elastic modulus, and fracture toughness of the composites with increasing SiC_w content, and an addition of 30 vol.-%SiC_w increases the fracture toughness from 3·42 MN m^?3/2 for the unreinforced matrix to 5·83 MN m^?3/2. The flexural strength is increased from 293 MN m^?2 for the unreinforced matrix to a maximum of 372 MN m^?2 by an addition of 10 vol.-%SiC_w, then it is significantly decreased by further increasing the SiC_w content. Observations via transmission electron microscopy show that no distinct second phase or intermediate layers form at the SiC_w/ZrO₂ interface. Diffusional separation of tetragonal phase from the cubic matrix occurred during cooling after hot pressing. Whisker bridging and crack deflection are the main toughening mechanisms, but whisker pull-out, crack branching, and refinement of the matrix particles also contribute to the improvement in the fracture toughness.

MST/1747