Dielectric, electrical and optical properties of a Ni-substituted double perovskite ceramic

Dielectric, electrical and optical properties of a Ni-substituted double perovskite ceramic

In this report, iron based double perovskite oxide Ca 2 Fe 0.85 Ni 0.15 NbO 6 was successfully synthesized adopting the solid state reaction method. The structure and microstructure along with the purity, frequency and temperature dependent dielectric properties, energy storage and band gap modulati...

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Bibliographic Details
Published in:Ferroelectrics Vol. 618; no. 1; pp. 259 - 273
Main Authors: Mohanty, S., Behera, S.
Format: Journal Article
Language:English
Published: Philadelphia Taylor & Francis 02-01-2024
Taylor & Francis Ltd
Subjects:
ac conductivity
Ceramics
Coercivity
Dielectric properties
Electrical properties
Energy gap
Energy storage
Ferroelectricity
Ferromagnetism
Frequency variation
High temperature
Hopping conduction
Hysteresis loops
M-H loop
Optical properties
P-E loop
Perovskites
Photovoltaics
Room temperature
SEM
Temperature dependence
UV-Visible
XRD
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Summary:In this report, iron based double perovskite oxide Ca 2 Fe 0.85 Ni 0.15 NbO 6 was successfully synthesized adopting the solid state reaction method. The structure and microstructure along with the purity, frequency and temperature dependent dielectric properties, energy storage and band gap modulation properties of the ceramic is also discussed. The ceramic shows a small band gap with a high remnant polarization which aligns it toward ferroelectric photovoltaic device applications. The temperature stable dielectric constant of the material up to a high temperature range is useful for MLCC applications. The energy storage density of the material is calculated from room temperature hysteresis loop. The frequency variation of ac conductivity refers Jonscher's law. The temperature variation of frequency exponent term n indicates CBH (correlated barrier hopping), model of the conduction mechanism in the sample. The presence of room temperature M-H loop with negligible magnetization and coercive value indicates the soft ferromagnetic behavior of the ceramic.
ISSN:0015-0193
1563-5112
DOI:10.1080/00150193.2023.2271331