Physical properties of Cd0.3Ni0.2Co0.3Cu0.2Fe2O4 spinel ferrites under different calcination temperatures

In this study, we examined the effect of calcination temperature on the structural, electrical transport and optical characteristics of Cd 0.3 Ni 0.2 Co 0.3 Cu 0.2 Fe 2 O 4 spinel ferrites. The samples, designated as S850 and S950, were prepared using sol-gel method, followed by calcination at 850 °...

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Bibliographic Details
Published in:Journal of sol-gel science and technology 2024-03, Vol.109 (3), p.654-674
Main Authors: Dhahri, Jamila, Hcini, Fakher, Hcini, Sobhi, Amorri, Omeyma, Charguia, Raihane, Khirouni, Kamel
Format: Article
Language:English
Subjects:
Absorption
Activation energy
Ceramics
Chemistry and Materials Science
Composites
Crystal defects
Crystallites
Crystallization
Dielectric loss
Energy
Energy gap
Energy value
Equivalent circuits
Ferrites
Glass
Grain boundaries
Inorganic Chemistry
Materials Science
Mathematical models
Microwaves
Nanotechnology
Natural Materials
Nyquist plots
Optical and Electronic Materials
Optical properties
Original Paper
Parameters
Penetration depth
Permittivity
Physical properties
Refractivity
Roasting
Sol-gel processes
Spinel
Structural analysis
Synthesis
Temperature
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Summary:In this study, we examined the effect of calcination temperature on the structural, electrical transport and optical characteristics of Cd 0.3 Ni 0.2 Co 0.3 Cu 0.2 Fe 2 O 4 spinel ferrites. The samples, designated as S850 and S950, were prepared using sol-gel method, followed by calcination at 850 °C and 950 °C, respectively. The structural analysis for the samples S850 and S950 reveals its crystallization in the cubic spinel structure ( F d 3 ¯ m space group ). Subsequently, as the temperature of calcination increased there was an increasing trend observed in both the unit cell parameters and average crystallite size. In addition, we studied the optical properties of the samples. Using Tauc” s reflectance method, the optical band gap energy values ( E g ) were estimated. These analyses confirmed the direct optical transitions of the samples. Furthermore, the direct band-gap energies for S850 and S950 were found as E gd  = 1.875 eV and E gd  = 1.746 eV, respectively. Then, the calculated low Urbach energies ( E u  = 1.05 eV for S850 and E u  = 1.01 eV for S950) revealed the high quality of our samples. This observation implies that increasing the calcination temperature reduces the level of disorder and defects. The study also investigated the changes in optical constants, like the extinction coefficient and penetration depth, as a function of wavelength. The refractive index changes were used to determine the Cauchy parameters, while the Wemple-Didomenico equation was utilized to estimate the energy parameters related to dispersion. The research also focused on analyzing the optical dielectric and optical conductivity constants. Increased calcination temperature also decreases band-gap energy ( E g ) and activation energy ( E a ). Equivalent circuit modeling of Nyquist plots indicates that both grain and grain boundary contributions influence the conduction mechanism in the specimens. The Overlapping-Large Polaron Tunneling (OLPT) model was employed to elucidate the conduction mechanism observed in the specimens. Moreover, when subjected to high frequencies, the synthesized materials demonstrate reduced dielectric constants and minimal dielectric losses. Additionally, they exhibit heightened electrical resistivity under these conditions. These features make the Cd 0.3 Ni 0.2 Co 0.3 Cu 0.2 Fe 2 O 4 materials a potential choice for applications that require absorption of microwaves and high-frequency signals. Graphical Abstract Highlights The samples were p
ISSN:0928-0707
1573-4846
DOI:10.1007/s10971-023-06303-7