Sintering mechanism of fine zirconia powders with alumina added by various ways

Koji Matsui, Takanori Yamakawa, Masato Uehara, Naoya Enomoto, Junichi Hojo

    Research output: Contribution to journalArticlepeer-review


    Small amounts of Al2O3 were added to fine zirconia powder by different ways: powder mixing, hydrolysis of alkoxide, and homogeneous precipitation. During a constant rate heating process, the Al2O 3 addition slightly raised the starting temperature of densification of powder compact, and the densification was remarkably stimulated by Al 2O3 at temperatures above about 1100°C. According to an isothermal analysis of densification, the densification rate was retarded by Al2O3 addition just after the start of sintering and then the densification rate increased significantly during sintering compared to Al2O3-free powder. These results mean that Al 2O3 particles pinned the shrinkage of zirconia powder compact at the initial stage, and diffuse toward zirconia surface to enhance the sintering. The sintering mechanism was explained by the grain-boundary diffusion for the Al2O3-free powder and the volume diffusion for Al2O3-added powder. When the Al 2O3 was added to zirconia powder by homogeneous precipitation and alkoxide methods, the densification rate was more stimulated compared to powder mixing method. The sintering mechanism did not change by the way for Al2O3 addition. The Al2O3 addition by the chemical process tended to enhance the grain growth of zirconia, while the uniform microstructure was achieved because of homogeneous addition of Al2O3 by these chemical processes.

    Original languageEnglish
    Pages (from-to)219-222
    Number of pages4
    JournalKey Engineering Materials
    Publication statusPublished - 2007

    All Science Journal Classification (ASJC) codes

    • General Materials Science
    • Mechanics of Materials
    • Mechanical Engineering


    Dive into the research topics of 'Sintering mechanism of fine zirconia powders with alumina added by various ways'. Together they form a unique fingerprint.

    Cite this