Amorphous phases and composition dependence of piezoelectricity in BaTiO3–Bi2O3 polar amorphous ceramics

Abstract

Composite ceramics with the nominal formula BaTiO3–xBi2O3 (x=0.15, 0.2, 0.25, 0.5, 0.667 and (1) were sintered under a small thermal gradient. After sintering, the monoclinic α Bi2O3 changed into cubic Bi12TiO20 and a very small amount of rhombohedral Bi8.11Ba0.89O13.05 in the x=0.2–1 samples; both direct and converse piezoelectric effects were observed for these samples without undergoing the electrical poling process. Because these composites do not contain obviously oriented grains and their piezoelectricity does not depend on ferroelectricity, temperature gradient-driven plastic flexoelectricity of the grain boundary amorphous phases may be the main poling mechanism. In this study, the largest value of the d33 piezoelectric constant of approximately 12pC/N was found in the x=0.667 sample; this sample also exhibits the highest amorphous content. The depoling temperature of this type of polar material is determined solely by the melting temperature of Bi12TiO20, favoring the potential use of these composites as piezoelectric materials for high-temperature applications.