Grain Growth Behavior of Alumina Compact Processed by Controlled Fracture Forming

Abstract

The effect of the green microstructure in the swaged Al₂O₃ with 98% reduction in area by the controlled fracture forming (CFF) on its grain growth behavior was investigated. The kinetics of grain growth in the Al₂O₃ compacts fabricated by the CFF process and by conventional process was estimated. The results indicate that both Al₂O₃ compacts obey a cubic law, but the grain growth rate constant K of the conventionally processed Al₂O₃ is 6 times as large as that of the swaged Al₂O₃ with 98% reduction in area. The retardation of grain growth in the swaged Al₂O₃ is attributed to the pores which are homogeneously distributed in the microstructure due to the flow and rearrangement of particles during the CFF process. The increase in number of pores per grain is responsible for the decrease in velocity of grain boundary migration. The mechanism for retardation of grain growth in the swaged Al₂O₃ is considered to be the pore-controlled mechanism.