Structural, Magnetic, and Mossbauer Parameters' Evaluation of Sonochemically Synthesized Rare Earth Er3+ and Y3+ Ions-Substituted Manganese-Zinc Nanospinel Ferrites
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info:eu-repo/semantics/openAccessTarih
2021Yazar
Almessiere, Munirah AbdullahGüner, Sadık
Güngüneş, Hakan
Sertkol, Murat
Slimani, Yassine
Badar, Rabail
Baykal, Abdulhadi
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Almessiere, M. A., Güner, S., Gungunes, H., Sertkol, M., Slimani, Y., Badar, R., ... & Baykal, A. (2021). Structural, Magnetic, and Mossbauer Parameters’ Evaluation of Sonochemically Synthesized Rare Earth Er3+ and Y3+ Ions-Substituted Manganese–Zinc Nanospinel Ferrites. ACS omega, 6(34), 22429-22438.Özet
The effect of Er3+ and Y3+ ion-co-substituted Mn0.5Zn0.5ErxYxFe2-2xO4 (MZErYF) (x <= 0.10) spinel nanoferrites (SNFs) prepared by a sonochemical approach was investigated. Surface and phase analyses were carried out using SEM, TEM, and XRD. Hyperfine parameters were determined by fitting room-temperature (RT) Mossbauer spectra. Magnetic field-dependent magnetization data unveiled the superparamagnetic nature at RT and ferrimagnetic nature at 10 K. RT saturation magnetization (M-S) and calculated magnetic moments (n(B)) are 34.84 emu/g and 1.47 mu(B), respectively, and have indirect proportionalities with increasing ion content. M-S and n(B) data have a similar trend at 10 K including remanent magnetizations (M-r). The measured coercivities (H-C) are between 250 and 415 Oe. The calculated squareness ratios are in the range of 0.152-0.321 for NPs and assign the multidomain nature for NPs at 10 K. The extracted effective magnetocrystalline constants (K-eff) have an order of 104 erg/g except for Mn0.5Zn0.5Er0.10Y0.10Fe1.80O4 SNFs that has 3.37 x 10(5) erg/g. This sample exhibits the greatest magnetic hardness with the largest magnitude of H-C = 415 Oe and an internal anisotropy field H-a = 1288 Oe among all magnetically soft NPs.