Optimizing design of the microstructure of sol-gel derived BaTiO ₃ ceramics by artificial neural networks

Modeling and application of artificial neural network (ANN) technique to the formulation design of BaTiO₃-based ceramics were carried out. Based on the homogenous experimental design, the results of BaTiO ₃-based ceramics were analyzed using a three-layer back propagation (BP) network model. Then the influence of sintering temperatures, holding time, donor additives (La₂O₃, MnO₂, Ce ₂O₃) and sintering aids (Al₂O ₃-SiO₂-TiO₂ (AST)) on the average grain size (d _a), the degree of grain uniformity given by the ratio of the maximal grain size to the average grain size (d _max/d _a), and the relative density (D _r) of doped BaTiO₃ ceramics system was investigated. The optimized results and experiment data were expressed and analyzed by intuitive graphics. Based on input data and output data, the sintering behavior of BaTiO₃ nano-powder was explained well. Furthermore, the fine and uniform microstructure of sol-gel derived BaTiO ₃ ceramics with d _a≤3 μm, d _max/d _a≤1.20, and D _r≥98% was obtained.