Abstract
The natural semilog characterisation of real part of the permittivity of PVTri/BaFe
12O
19 composite as a function of frequency,
ω for various temperatures from RT up to 120
°C. The inset shows the variation of the exponent
n in the formula with temperature.
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► PVTri coated BaFe
12O
19 nanoparticles have been prepared by the citrate sol–gel synthesis of BaFe
12O
19 and in situ polymerization of PVTri. ► So far PVTri coated BaFe
12O
19 nanoparticles have not been synthesized. ► As composite, its conductivity, structural, thermal, morphological dielectric, and magnetic evaluation were performed and results are reported in detail.
The production of PVTri–BaFe
12O
19 composites was carried out by in situ polymerization of PVTri in the presence of synthesized BaFe
12O
19 particles. Crystalline phase was determined as BaFe
12O
19 by XRD analysis and thermal analysis revealed an inorganic content of ∼45% in the composite. SEM and TEM analyses showed strongly agglomerated particles in the range of 200
nm to several micrometers in the composite. The dielectric function of the various temperatures showed frequency dependency in a reciprocal power law. The dissipation (or loss) of energy stored within the composite was found to obey the reciprocal rule of power law of the frequency dependency. The real part of electrical modulus formalism increased exponentially with frequency for various temperatures, reaching a constant value and finally saturated. The imaginary part showed a reciprocal power law against the applied frequency and shifted to higher frequency at elevated temperatures. Magnetization measurements revealed substantially lower saturation magnetization of the composite material as compared to the bulk barium ferrite powders, possibly due to pinning of some of the surface spins by the adsorption of the PVTri molecules to the surface of the BaFe
12O
19.