Abstract
Spinel cobalt ferrite/hexagonal strontium hexaferrite (2CoFe2O4/SrFe12−2xSmxLaxO19; x = 0.2, 0.5, 1.0, 1.5) nanocomposites were fabricated using the tartaric acid precursor pathway, and the effects of La3+–Sm3+ double substitution on the formation, structure, and magnetic properties of CoFe2O4/SrFe12−2xSmxLaxO19 nanocomposite at different annealing temperatures were assayed through X-ray diffraction, scanning electron microscopy, and vibrating sample magnetometry. A pure 2CoFe2O4/SrFe12O19 nanocomposite was obtained from the tartrate precursor complex annealed at 1100 °C for 2 h. The substitution of Fe3+ ion by Sm3–+La3+ions promoted the formation of pure 2CoFe2O4/SrFe12O19 nanocomposite at 1100 °C. The positions and intensities of the strongest peaks of hexagonal ferrite changed after Sm3+–La3+ substitution at ≤1100 °C. In addition, samples with an Sm3+–La3+ ratio of ≥1.0 annealed at 1200 °C for 2 h showed diffraction peaks for lanthanum cobalt oxide (La3Co3O8; dominant phase) and samarium ferrite (SmFeO3). The crystallite size range at all constituent phases was in the nanocrystalline range, from 39.4 nm to 122.4 nm. The average crystallite size of SrFe12O19 phase increased with the number of Sm3+–La3+ substitutions, whereas that of CoFe2O4 phase decreased with an x of up to 0.5. La–Sm co-doped ion substitution increased the saturation magnetization (Ms) value and the subrogated ratio to 0.2, and the Ms value decreased with the increasing number of double substitutions. A high saturation magnetization value (Ms = 69.6 emu/g) was obtained using a La3+–Sm3+ co-doped ratio of 0.2 at 1200 for 2 h, and a high coercive force value (Hc = 1192.0 Oe) was acquired using the same ratio at 1000 °C.
Highlights
The consolidation of spinel soft and hard ferrites in nanocomposites can considerably change the magnetic characteristics related to interfacial exchange coupling
30.32◦, 35.49◦, 43.13◦, 53.48◦, 57.04◦, and 63.05◦ ; whereas peaks associated with the strongest diffraction planes (114), (107), (0 0 8) (110), (203), (2200), and (2011) of hexagonal SrFe12 O19 were differentiated at 2θ values of 34.17◦, 32.31◦, 31.085◦, 30.34◦, 37.15◦, 63.16◦, and 56.8◦
When the annealing temperature was increased from 1000 ◦ C and 1200 ◦ C within 2 h, well-defined cubic cobalt ferrite CoFe2 O4 and M-type strontium hexaferrite SrFe12 O19 nanocomposite was formed
Summary
The consolidation of spinel soft and hard ferrites in nanocomposites can considerably change the magnetic characteristics related to interfacial exchange coupling. Nanocomposite magnets offer wide-band absorption, with a megahertz (spinel ferrites MFe2 O4 , where M = divalent ion, such as Cu, Zn, Cd, Co, Ni, Mn, or mixture of two divalent ions) to gigahertz (hard ferrites) range. Strontium hexaferrite (SrFe12 O19 ) M-type ferrite is the most well-known hard ferrite, owing to its merits, such as low cost, high saturation magnetization, high magnetization, high coercive force, excellent corrosion resistance, eminent chemical stability, and high Curie temperature (470 ◦ C). It has a wide application range, in the fields of automotives, home appliances, electronics, lighting, biomedical and diagnostic applications, and oil and energy [5]. The structural and magnetic properties were reorganized through X-ray powder profiling, scanning electron microscopy, transmission electron microscopy, and vibration sample magnetometry
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