On the structure-property relationships of (Al, Ga, In)-doped spinel cobalt ferrite compounds: a combined experimental and DFT study

We report a combined experimental and theoretical study of pure and doped cobalt ferrite where 25% of Fe 3+ ions were replaced by Al 3+ , Ga 3+ , and In 3+ ions, respectively, i.e. , CoFe 1.5 X 0.5 O 4 (X = Al, Ga, and In). The ferrite compositions were successfully synthesized using the solid-state...

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Published in:Physical chemistry chemical physics : PCCP 2021-09, Vol.23 (33), p.18112-18124
Main Authors: Naveed-Ul-Haq, M, Hussain, Shahzad, Webers, Samira, Salamon, Soma, Ahmad, Ibtisam, Bibi, Tayyaba, Hameed, Amna, Wende, Heiko
Format: Article
Language:English
Subjects:
Cobalt compounds
Cobalt ferrites
Composition
Density functional theory
Dopants
Doping
Electronic structure
Energy gap
Ferric ions
Gallium
Lattice parameters
Magnetic moments
Magnetic properties
Mathematical analysis
Spectrum analysis
Spinel
Ultraviolet reflection
Ultraviolet spectra
Unit cell
X ray powder diffraction
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Summary:We report a combined experimental and theoretical study of pure and doped cobalt ferrite where 25% of Fe 3+ ions were replaced by Al 3+ , Ga 3+ , and In 3+ ions, respectively, i.e. , CoFe 1.5 X 0.5 O 4 (X = Al, Ga, and In). The ferrite compositions were successfully synthesized using the solid-state reaction method. The X-ray powder diffraction method established that all ferrite samples had a spinel unit cell structure with the Fd 3&cmb.macr; m (No. 227) space group. The lattice constants of ferrites increased from 8.382 Å (for undoped CoFe 2 O 4 ) to 8.520 Å (for In-doped cobalt ferrite) in direct relation to the dopant ion size. The magnetic properties were obtained at 4.3 K and 300 K. At 4.3 K, the In-doped CoFe 2 O 4 showed the highest saturation magnetic moment of 4.68 μ B f.u. −1 , while Al-doped CoFe 2 O 4 showed the smallest value of 2.72 μ B f.u. −1 . The Fe 3+ distribution among the spinel tetrahedral and octahedral sites was determined from the Mössbauer spectra. From ultraviolet-visible diffuse reflectance spectroscopy the direct optical bandgaps were determined, which have values between 1.20 eV and 1.28 eV for these ferrites. The ferrite compositions were also studied theoretically using plane-wave density functional theory using the CASTEP code where it was revealed that arrangements of the non-magnetic cations at the tetrahedral and octahedral sites strongly influence the electronic structure, the bandgap value, and the net magnetic moment per formula unit. Light Al 3+ ions at the octahedral site give a low value of the net magnetic moment while the heavier Ga 3+ and In 3+ ions at the tetrahedral sites of the spinel give an enhanced magnetic moment. The magnetic moment values obtained from theoretical calculations match very well with the experimental values. Moreover, the theoretical calculations reveal that there exists a strong p-d hybridization among the oxygen and magnetic ions, which is affected by the non-magnetic dopant ions. The change in hybridization with the non-magnetic ion doping is responsible for the altered magnetic moments of the doped ferrites. Thus, our study provides a comprehensive investigation covering the synthesis and characterization of ferrites along with a good understanding of the phenomenon of how non-magnetic ion doping into spinel ferrites provides a method to tune the electronic and magnetic properties of the spinel ferrite. A combined experimental and theoretical study to determine how the replacement of
ISSN:1463-9076
1463-9084
DOI:10.1039/d1cp02625a