%0 Journal Article
%F self-archiving-INPE-MCTIC-GOV-BR
%A Hirschmann, Ana C. O.,
%A Nono, Maria do Carmo Andrade,
%A Riehl, R. R.,
%A Silva, C. R. M.,
%@affiliation Instituto Nacional de Pesquisas Espaciais (INPE)
%@affiliation Instituto Nacional de Pesquisas Espaciais (INPE)
%@affiliation Instituto Nacional de Pesquisas Espaciais (INPE)
%@affiliation CTA
%T Processing and Microstructural Characterization of Porous Alumina-Zirconia Ceramic Using Cmc And PVC
%B Materials Science Forum. Advanced Powder Technology VI Book Series
%D 2008
%V 591/593
%8 10.4028/
%K alumina and zirconia, porous ceramics.
%X Porous materials are of significant interest due to their wide application in catalysis, separation, lightweight structural materials, biomaterials and other areas. Porous ceramics are produced within a wide range of porosities and pore sizes depending on the application intended. Porosity and pore size distribution can be carefully controlled by the choice of organic composite and the amount added. The material may have two types of pores: open and closed pores. The open pores, also called interconnected pores, are those which are in contact with the external surface of the material, being very useful for the manufacture of ceramic filters. A high number of closed pores are important for the manufacturing of materials used in thermal applications. There are many methods for obtaining porous ceramics, in general consisting in adding to the ceramic matrix organic particles, which volatilize during the first heat-up. The objective of this study was to produce ceramic composite nanostructure of alumina and yttria stabilized zirconia (Y-TZP) with micrometric pore sizes. The effects of ZrO2 additions in the mechanical properties of Al2O3 have been intensively investigated, due to the possible increase of the mechanical strength of this material. The organic particles used to create the pores were CMC and PVC. The microstructure of the porous ceramic samples obtained was evaluated considering the degree of sinterization of the nanoparticles, pores formation, porosity, specific surface of the pores and the distribution of the interconnecting pores.
%P 510-513
%@language en
%3 Hirschmann_processing.pdf