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The Influence of Lanthanum Admixture on Microstructure and Electrophysical Properties of Lead-Free Barium Iron Niobate Ceramics.

Dariusz BochenekDagmara BrzezińskaPrzemysław NiemiecLucjan Kozielski
Published in: Materials (Basel, Switzerland) (2024)
This article presents the research results of lead-free Ba 1-3/2 x La x (Fe 0.5 Nb 0.5 )O 3 (BFN x La) ceramic materials doped with La ( x = 0.00-0.06) obtained via the solid-state reaction method. The tests of the BFN x La ceramic samples included structural (X-ray), morphological (SEM, EDS, EPMA), DC electrical conductivity, and dielectric measurements. For all BFN x La ceramic samples, the X-ray tests revealed a perovskite-type cubic structure with the space group P m 3¯ m . In the case of the samples with the highest amount of lanthanum, i.e., for x = 0.04 (BFN4La) and x = 0.06 (BFN6La), the X-ray analysis also showed a small amount of pyrochlore LaNbO 4 secondary phase. In the microstructure of BFN x La ceramic samples, the average grain size decreases with increasing La content, affecting their dielectric properties. The BFN ceramics show relaxation properties, diffusion phase transition, and very high permittivity at room temperature (56,750 for 1 kHz). The admixture of lanthanum diminishes the permittivity values but effectively reduces the dielectric loss and electrical conductivity of the BFN x La ceramic samples. All BFN x La samples show a Debye-like relaxation behavior at lower frequencies; the frequency dispersion of the dielectric constant becomes weaker with increasing admixtures of lanthanum. Research has shown that using an appropriate amount of lanthanum introduced to BFN can obtain high permittivity values while decreasing dielectric loss and electrical conductivity, which predisposes them to energy storage applications.
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