Electric-field-induced antiferroelectric to ferroelectric phase transition in polycrystalline NaNbO3

反铁电性 材料科学 铁电性 相变 凝聚态物理 电场 压电 微晶 电介质 相(物质) 光电子学 复合材料 化学 物理 量子力学 有机化学 冶金
作者
Mao‐Hua Zhang,Lovro Fulanović,Sonja Egert,Hui Ding,Pedro B. Groszewicz,Hans‐Joachim Kleebe,Leopoldo Molina‐Luna,Jurij Koruza
出处
期刊:Acta Materialia [Elsevier BV]
卷期号:200: 127-135 被引量:139
标识
DOI:10.1016/j.actamat.2020.09.002
摘要

Electric-field-induced phase transitions are the most important characteristics of antiferroelectric materials. However, in several prototype antiferroelectrics, these transitions are irreversible and the origin of this behavior is poorly understood. This prevents their widespread use, for example, in energy storage and memory applications. Here, we investigated the antiferroelectric-ferroelectric phase transitions in polycrystalline NaNbO3, a material recently suggested as the basis for lead-free antiferroelectrics with high energy storage densities. An irreversible transition from the antiferroelectric state to a new state showing macroscopic piezoelectricity (d33=35 pC/N) was induced at 11.6 kV/mm (room temperature, 1 Hz), accompanied by a 33% drop in permittivity. Microscopically, a change from a translational antiferroelectric domain structure to a wedge-shaped ferroelectric domain structure was observed using transmission electron microscopy. 23Na solid-state nuclear magnetic resonance allowed for a detailed study of the local structure and revealed pure antiferroelectric and coexisting antiferroelectric/ferroelectric nature of the samples before and after the application of an electric field, respectively. Interestingly, despite the large electric fields applied, only 50±5% of the material underwent the antiferroelectric-ferroelectric phase transition, which was related to the material´s microstructure. The temperature- and frequency-dependence of the phase transition was studied and compared to the behavior observed in lead-based antiferroelectric systems.
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