Reaction-Bonded Mullite/Zirconia Composites

The feasibility of fabricating dense, low-shrinkage, mullite/ ZrO₂ composites based on the reaction bonding of alumina (RBAO) process and the reaction sintering of zircon is examined. Compacts pressed from an attrition-milled powder mixture of Al, A1₂O₃ and zircon were heated in air according to a two-step heating cycle. The phase evolution and microstructural development during reaction bonding were traced by X-ray diffraction, nuclear magnetic resonance, and scanning electron microscopy on samples extracted from various points along the heating cycle. It is seen that, as in conventional RBAO, AI oxidizes to γ-Al₂O₃ which then transforms to α-AI₂O₃ between 1100° and 1200°C. The zircon dissociation commences at ∼1400°C and is practically complete by 1500°C. Mullite enriched in Al₂O₃ forms initially, but 3:2 stoichiometry is attained in the final product which consists of mullite, t - and m-ZrO₂, and residual α-AI₂O₃. The flexure strength of the composite is superior to that of pure mullite, and ∼80% of the strength is retained up to 1200°C. Although there was no toughness enhancement relative to mullite, this should be achievable by optimizing the fabrication procedure.