Cluster-glass-like behavior in zinc ferrite nanograins

•Zn ferrites nanograins were prepared by milling and with grain sizes controlled by heat treatment.•Zn ferrites nanograins have a large number of cationic inversions and ordering temperature near to 300 K.•Zn ferrites, with grain sizes at 14–17 nm interval, still present uncompensated Fe spins.•Clus...

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Bibliographic Details
Published in:Journal of magnetism and magnetic materials 2018-12, Vol.467, p.1-7
Main Authors: Procopio, E.F., Larica, C., Muniz, E.P., Litterst, F.J., Passamani, E.C.
Format: Article
Language:English
Subjects:
57Fe Mössbauer spectroscopy
Annealing
Ball milling
Cluster glass
Clusters
Diffraction
Ferrites
Glass
Grain boundaries
Grain size
Hyperfine structure
Iron 57
Magnetic fields
Magnetic permeability
Magnetic properties
Magnetic susceptibility
Mossbauer spectroscopy
Organic chemistry
Phase transitions
Spinel
Temperature dependence
X-ray diffraction
Zinc ferrites
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Summary:•Zn ferrites nanograins were prepared by milling and with grain sizes controlled by heat treatment.•Zn ferrites nanograins have a large number of cationic inversions and ordering temperature near to 300 K.•Zn ferrites, with grain sizes at 14–17 nm interval, still present uncompensated Fe spins.•Cluster glass-like behavior observed below 30 K due to magnetic grain interactions. Structural and magnetic properties of ZnFe2O4 nanograins, prepared by high-energy ball milling and annealed, were systematically studied by X-ray diffraction, 57Fe Mössbauer spectroscopy and AC magnetic susceptibility measurements. Disordered spinel-like structure, with a grain size of 12 nm, is established after 200 h of milling. While the 300 K Mössbauer spectrum of the as-milled sample (200 h) displays broad magnetic absorption lines, characteristic of a disordered system, the magnetization data do not show a magnetic phase transition between 4 and 300 K. At low temperatures, the Mössbauer spectra suggest the presence of two distinct ferrite magnetic phases: one attributed to the grain core (crystalline-like phase), with magnetic ordering temperature of about 90 K, and one showing a magnetic hyperfine field distribution; the latter is associated with a chemically disordered phase (grain boundary contributions). Annealing the 200 h sample at 973 K leads to an improvement of atomic ordering of the spinel structure (reduction of cationic inversion) and average grain size of about 17 nm. AC magnetic susceptibility shows a cusp at about T≈30K, whilst Mössbauer experiments in the same sample reveal magnetic blocking in the same temperature range. The frequency dependence of susceptibility suggests the formation of a cluster-glass-like state. High temperature susceptibility can be described with a Fulcher law of interacting magnetic clusters.
ISSN:0304-8853
1873-4766
DOI:10.1016/j.jmmm.2018.07.057