Abstract
The magnetic properties of mesoscopic materials are modified by size and surface effects. We present a sol-gel method used to tailor these effects, and illustrate it on Co1+yAl2-yO4 spinel. Nanocomposites made of spinel oxide Co1+yAl2-yO4 particles dispersed in an amorphous SiO2 matrix were synthesized. Samples with various mass fractions -x of Co1+yAl2-yO4 in composite, ranging from predominantly SiO2 (x = 10 wt%) to predominantly spinel (x = 95 wt%), and with various Co concentrations in spinel y were studied. The spinel grain sizes were below 100 nm with a large size distribution, for samples with predominant spinel phase. Those samples showed Curie-Weiss paramagnetic behavior with antiferromagnetically interacting Co ions (? ? -100 K). The grain sizes of spinel stays confined in 100 nm range even in the spinel samples diluted with as low as 5 wt% concentration of amorphous SiO2. For the samples with predominant SiO2 the crystalline nanoparticles are well separated and of size of around 100 nm, but with presence of much smaller spinel nanoparticles of about 10 nm. The magnetic properties of the samples with predominant silica phase showed complex behavior, spin-glass magnetic freezing at the lowest temperatures and lower absolute value of ? and consequently lower exchange constant.
Highlights
Nanocomposites made of spinel oxide Co1+yAl2-yO4 particles dispersed in an amorphous SiO2 matrix were synthesized
Co1+yAl2-yO4 belongs to the group of magnetic spinel oxides
As magnetic nanoparticles usually tend to agglomerate due to their large surface energy and/or strong magnetic interactions, it is useful to study their magnetic properties in the form of nanocomposites
Summary
Co1+yAl2-yO4 belongs to the group of magnetic spinel oxides (represented with the general formula AB2O4). Variation of the magnetic cations distribution over the A and B sites can provoke different magnetic behavior in spinel compounds. Co3+ in B position is in low-spin state with no magnetic moment [1]. By decreasing particle size to nano dimensions, the finite size effects give rise to surface spin canting, superparamagnetism (SPM), and/or site disorder effect. Many factors determine magnetic behavior of nanosized system, like particle size and shape, size distribution, agglomeration, cation distribution, interparticle interactions. As magnetic nanoparticles usually tend to agglomerate due to their large surface energy and/or strong magnetic interactions, it is useful to study their magnetic properties in the form of nanocomposites.
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