Abstract

Definite increases in the Curie point (T C ) of undoped and lanthanum‐ (La‐) doped (<0.5 at.%) barium titanate (BaTiO 3 ) ceramics sintered at elevated temperatures in the range of 1300°‐1450°C were observed. Both undoped and 0.3 at.% La‐doped BaTiO 3 (chosen as a typical doping concentration to yield semiconducting materials) ceramics showed almost the same T C behavior; their T C values increased by ∼3.5°C as the sintering temperature was increased from 1300° to 1450°C. Semiconducting 0.3 at.% La‐doped materials increased in room‐temperature bulk resistivity and TC with increased sintering temperature. The bulk resistivity of the La‐doped materials, which was obtained from complex impedance analysis, increased from ∼2 omega cm for the material sintered at 1350°C to ∼6 ω cm at 1450°C. The phenomenon of bulk resistivity increase with sintering temperature was observed in the materials with a doping concentration of ≥ 0.2 at.% La, but was not observed in those doped with <0.2 at.% La. The mechanisms of TC and the bulk resistivity increase observed in the present materials with increased sintering temperature are discussed based on various models found in the literature, particularly in terms of the defect chemistry in semiconducting BaTiO 3 ceramics and the influence of liquid phases present during sintering.