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Significantly decreased depolarization hydrostatic pressure of 3D‐printed PZT95/5 ceramics with periodically distributed pores

Jicai Jia, Hengchang Nie, Xin He, Chun Feng, Min Zhu, Chengtie Wu, Genshui Wang, Xianlin Dong

2021Journal of the American Ceramic Society12 citationsDOI

Abstract

Abstract Pb 0.99 (Zr 0.95 Ti 0.05 ) 0.98 Nb 0.02 O 3 ferroelectric ceramics with porous structure of periodic distribution were fabricated successfully via Direct Ink Writing, a type of 3D printing technique. The effect of periodically distributed porous microstructure on the dielectric, ferroelectric, as well as hydrostatic‐pressure‐induced depolarization properties of PZT95/5 ferroelectric ceramics, was investigated. The printed porous ceramics exhibit relatively good viscoelasticity to retain the periodic structure during 3D printing and drying. In contrast with dense PZT95/5 ferroelectric ceramics prepared by conventional solid‐state sintering, low bulk density of the periodically distributed porous PZT95/5 ceramics leads to a decreased remanent polarization of 22.9 µC/cm 2 under 2 kV/mm. As the hydrostatic pressure increased, the poled periodically distributed porous PZT95/5 ceramics depolarize sharply under a low and narrow hydrostatic pressure range of 113–116 MPa with a released charge density of 23.9 µC/cm 2 , while the poled dense PZT95/5 ceramics depolarize under a range of 250–278 MPa. Therefore, the introduction of periodically distributed micropores into PZT95/5 ceramics decreases the ferroelectric‐to‐antiferroelectric phase transition hydrostatic pressure significantly and maintained relatively excellent other properties simultaneously, such as temperature stability and low dielectric loss. The almost sharp depolarization behavior under a significantly decreased hydrostatic pressure demonstrates that periodically distributed porous PZT95/5 ferroelectric ceramics fabricated controllably by 3D printing exhibit excellent performances and prospects in mechanical–electrical energy conversion applications.

Topics & Concepts

Materials scienceFerroelectricityCeramicDielectricPorosityComposite materialHydrostatic pressureMineralogyMicrostructureOptoelectronicsThermodynamicsChemistryPhysicsDielectric materials and actuatorsAdditive Manufacturing and 3D Printing TechnologiesFerroelectric and Piezoelectric Materials