Optical and electrical properties of a new complex oxide Pb1 / 3Na1 / 3K1 / 3Ta2 / 3Fe1 / 3O3-δ with perovskite structure

N.A. Zhuk, A.M. Popov, R.I. Korolev, V.V. Moroz, A.A. Selyutin, A.V. Koroleva, N.A. Sekushin, B.A. Makeev ORCID logo show affiliations and emails
Received 18 August 2022; Accepted 24 October 2022;
Citation: N.A. Zhuk, A.M. Popov, R.I. Korolev, V.V. Moroz, A.A. Selyutin, A.V. Koroleva, N.A. Sekushin, B.A. Makeev. Optical and electrical properties of a new complex oxide Pb1 / 3Na1 / 3K1 / 3Ta2 / 3Fe1 / 3O3-δ with perovskite structure. Lett. Mater., 2022, 12(4) 367-372
BibTex   https://doi.org/10.22226/2410-3535-2022-4-367-372

Abstract

A cubic perovskite of complex composition Pb1/3Na1/3K1/3Ta2/3Fe1/3O3-δ (sp. gr. Pm-3m, a = 3.9767(3) Å) was synthesized for the first time by the solid-phase reaction method.A cubic perovskite of complex composition Pb1 / 3Na1 / 3K1 / 3Ta2 / 3Fe1 / 3O3−δ (sp. gr. Pm-3m, a = 3.9767(3) Å) was synthesized for the first time by the solid-phase reaction method. The samples are characterized by an almost pore-free microstructure formed by slightly melted randomly oriented cubic crystallites. The band gap (≈2.05 eV) of a complex perovskite for a direct allowed electronic transition was calculated from the data of the diffuse reflection spectrum. According to impedance spectroscopy data, three polarization processes are observed in the sample at room temperature: low-frequency (at a frequency less than 300 Hz), medium-frequency (from 300 Hz to 10 kHz), and high-frequency (from 100 kHz to 10 MHz) ones. The permittivity of the sample at room temperature and a frequency of 107 Hz reaches high values of about 147, and the dielectric loss tangent does not exceed 0.12.

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