Reaction Mechanism of BaTiO₃ from Powder Compacts, BaCO₃ and TiO₂ and Expansion Phenomena during the Formation Process

Abstract

The formation process of BaTiO₃ from powder compacts, equi-molar mixture of BaCO₃ and TiO₂, and an abnormal expansion during the formation process were investigated. Powder compacts were fired for 30min in air atmosphere at various temperatures, up to 1200°C. The formation process of BaTiO₃ is devided into three steps; firstly, BaTiO₃ is formed at the contact points between BaCO₃ and TiO₂ particles, secondly, Ba₂TiO₄ is formed by the reaction of the prior-formed BaTiO₃ with BaCO₃, finally, BaTiO₃ is formed by the reaction of residual TiO₂ and Ba₂TiO₄. In the macroscopic observation, it was confirmed that a powder compact of BaCO₃ on magnesia and rutile substrates begins to melt at 950°C. This liquid phase is thought to influence the formation reaction of BaTiO₃ greatly. It is well known that Ba component diffuses to TiO₂ one-sidedly in this reaction. As a result, the space where BaCO₃ occupied in a compact specimen remains as a pore after the termination of reactions. Then, an increase in the volume happens by TiO₂'s changing in BaTiO₃. These are considered to be the cause of an abnormal expansion caused by the reaction of BaCO₃ and TiO₂.