Giant magnetodielectric effect in composites of nanodimensional spin glass of system CoO-SiO2 and mesoporous silica SBA-15

Giant magnetodielectric effect in composites of nanodimensional spin glass of system CoO-SiO2 and mesoporous silica SBA-15

•Nanocomposites of SBA-15 & spin glass of CoO-SiO2 were synthesized by simple method.•The materials exhibited very large magnetodielectric parameter in the range 523–49%.•Catalan’s model were used to explain the results.•Large negative MR of the nanodimensional spin glass phase causes such MD ef...

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Bibliographic Details
Published in:Journal of magnetism and magnetic materials Vol. 491; p. 165633
Main Authors: Maity, Anupam, Samanta, Subha, Maiti, Ramaprasad, Chatterjee, Soumi, Biswas, Debasish, Chakravorty, Dipankar
Format: Journal Article
Language:English
Published: Amsterdam Elsevier B.V 01-12-2019
Elsevier BV
Subjects:
Cobalt
Composition
Dissipation factor
Electrical resistivity
Electron spin
Magnetodielectric (MD)
Magnetoresistance
Magnetoresistance (MR)
Magnetoresistivity
Mathematical models
Mesoporous silica
Nanocomposite
Nanocomposites
Nanoglass
Parameters
Photoelectrons
Silica gel
Silica glass
Silicon dioxide
Sol-gel
Sol-gel processes
Spin glasses
X ray photoelectron spectroscopy
Nanoglass
Nanocomposite
Magnetodielectric (MD)
Mesoporous silica
Sol-gel
Magnetoresistance (MR)
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Summary:•Nanocomposites of SBA-15 & spin glass of CoO-SiO2 were synthesized by simple method.•The materials exhibited very large magnetodielectric parameter in the range 523–49%.•Catalan’s model were used to explain the results.•Large negative MR of the nanodimensional spin glass phase causes such MD effect.•Applications could be as magnetic sensors & magnetically controlled supercapacitors. Nanodimensional silica-based spin glasses of compositions xCoO-(100-x)SiO2 with x having values 20 and 30 were synthesized by sol-gel method within mesoporous silica SBA-15 (Santa Barbara Amorphous-15) having a pore diameter ~5.5 nm. X-ray photoelectron spectroscopy (XPS) analysis showed the presence of both Co2+ and Co3+ species within the glasses. This caused electronic conduction in this amorphous system. The nanoglasses exhibited resistivity values at room temperature which were about three orders of magnitude lower than those of the corresponding bulk glasses. The resistivity data for the nanodimensional glasses on analysis confirmed the conduction to arise due to small polaron hopping between the localized states represented by these ions with an activation energy in the range 0.08–0.07 eV. The inter-site separation values extracted from the analysis of the resistivity data were found to lie in the range 6.7–6.6 Å. The values of magnetodielectric (MD) parameter for the different nanocomposites were rather large with the highest value found to be in the range 523–49% for the frequencies 1 kHz and 1 MHz in case of nanocomposite with a glass composition 30CoO-70SiO2. The dissipation factor for the samples was, however, in the range 0.3–1.6. By using suitable measuring frequency the dissipation factor could be brought down to a value less than 1.0 with the M.D. parameter exhibiting values in the range 10–49%. The results were fitted to Catalan’s model based on two dielectrics with different resistivity values connected in series. The satisfactory fit of the experimental data to the theoretical model based on a negative magnetoresistance of the nanoglasses leads to the conclusion that an enhancement of spin polarized electron hopping is the reason behind this effect. The results obtained should be further explored to find applications of these materials as magnetic sensors as well as magnetically controlled supercapacitors.
ISSN:0304-8853
1873-4766
DOI:10.1016/j.jmmm.2019.165633