Abstract
Domain wall motion in ferroics, similar to dislocation motion in metals, can be tuned by well-concepted microstructural elements. In demanding high-power applications of piezoelectric materials, the domain wall motion is considered as a lossy hysteretic mechanism that should be restricted. Current applications for so-called hard piezoelectrics are abundant and hinge on the use of an acceptor-doping scheme. However, this mechanism features severe limitations due to enhanced mobility of oxygen vacancies at moderate temperatures. By analogy with metal technology, the authors present here a new solution for electroceramics, where precipitates are utilized to pin domain walls and improve piezoelectric properties. Through a sequence of sintering, nucleation, and precipitate growth, intragranular precipitates leading to a fine domain structure are developed as shown by transmission electron microscopy, piezoresponse force microscopy, and phase-field simulation. This structure impedes the domain wall motion as elucidated by electromechanical characterization. As a result, the mechanical quality factor is increased by ≈50% and the hysteresis in electrostrain is suppressed considerably. This is even achieved with slightly increased piezoelectric coefficient and electromechanical coupling factor. This novel process can be smoothly implemented in industrial production processes and is accessible to simple laboratory experimentation for microstructure optimization and implementation in various ferroelectric systems.
Highlights
Authors Changhao Zhao, Shuang Gao, Tiannan Yang, Michael Scherer, Jan Schultheiß, Dennis Meier, Xiaoli Tan, Hans-Joachim Kleebe, Long-Qing Chen, Jurij Koruza, and Jürgen Rödel
This results in a supersaturated solid solution, which is metastable at room temperature.[14,38]
Precipitate formation in the model system BaTiO3 alloyed with CaTiO3 has been demonstrated to: a
Summary
The BCT20 samples were synthesized by the solid-state reaction method. Starting powders of BaCO3 (Alfa Aesar, 99.95%), CaCO3 (Alfa Aesar, 99.99%), and TiO2 (Anatase, Alfa Aesar, 99.6%) were weighed according to stoichiometry. The samples were air-quenched, that is, they were directly taken out of the tube furnace from 1500 °C to room temperature, to kinetically suppress the formation of the Ca-rich secondary phase. Those as-quenched samples (unaged samples) were denoted as Su. For the aging treatment, the asquenched samples were annealed at 1200 °C for 72 h and cooled with 5 K min−1 and were denoted as So. Some of the 1200 °C-annealed samples were further annealed at 1300 °C for 24 h and were denoted as St
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