Abstract:
This dissertation presents a systematic study on five series of spinel ferrites. Three series
of spinel ferrites, namely, NiY-ferrites (NiY2xFe2-2xO4, x = 0.0 – 0.12, step: 0.02), MgY-ferrites
(MgY2xFe2-2xO4, x = 0.0 – 0.12, step: 0.02) and NiZnY-ferrites (Ni0.6Zn0.4Y2xFe2-2xO4, x = 0.0 -
0.1, step: 0.02) were fabricated in a polycrystalline form by double sintering ceramic method.
Two series of CoZnY-ferrites (Co1-xZnxY0.15Fe1.85O4, x = 0.0, 0.2, 0.4, 0.6, 0.8, 1.0) and
CoY-
ferrites (CoFe2O4 + x Y2O3, x = 0 wt %, 1 wt %, 3 wt %, 5 wt %) were fabricated by co-
precipitation method. The samples were characterized by X-ray diffraction (XRD), Scanning
Electron Microscopy (SEM), Fourier Transform Infrared Spectroscopy (FTIR), Vibrating
Sample Magnetometery (VSM) and Impedance spectroscopy and Ferromagnetic Resonance.
Phase analysis of NiY-, MgY- and NiZnY-ferrites from XRD patterns has shown cubic
spinel single phase along with few traces of second phase identified as orthorhombic phase. This
phase becomes more conspicuous for higher concentration of yttrium. The lattice constant as a
function of yttrium contents changes non-linearly. The behavior of the lattice parameter was
explained on the basis of differences in ionic radii of the constituent ions. Analysis of the XRD
patterns of the CoZnY-ferrites confirms the formation of cubic spinel phase along with second
phase of YFeO3. The lattice seems to expand to accommodate the increased number of Zn2+ ions
of relatively larger ionic radii. The phase analysis of the XRD patterns of CoY-ferrites shows
that all the samples are dual phase except the sample with x = 0 wt %. The lattice constant was
found to decrease with yttrium contents. The lattice seems to compress by the presence of second
phase due to difference in thermal expansion coefficients. X-ray density and physical density
was found to increase whereas porosity was found to decrease with the increase of yttrium
contents. The morphology of the samples shows non-homogeneous distribution of grains in all
the samples except CoZnY-ferrites. The near uniform distribution of grain size was observed in
CoZnY ferrites. FTIR spectra of NiY-, MgY- and NiZnY-ferrites observed at room temperature
in the wave number range 370 – 1100 cm-1 exhibit splitting of the two fundamental absorption
bands, thereby confirming the solid state reaction. FMR spectra of NiY- and MgY-ferrites were
measured at room temperature at X-band (9.5 GHz). The nominal compositions MgY0.04Fe1.96O4
and NiY0.12Fe1.88O4 have small linewidth, ΔH = 269 Oe and 282 Oe respectively. Hence these
ferrites have potential for high frequency applications. A systematic study of variations in
resistivity with different concentration of yttrium has been carried out to optimize the resistivity.
The room temperature resistivity shows an increasing trend in all series whereas it was decreased
in case of Co-Zn-Y ferrites. The addition of Y3+ ions in place of Fe3+ ions reduce the degree of
conduction by blocking Verwey’s hopping mechanism resulting in an increase of resistivity. The
temperature dependent dc resistivity was found to decrease linearly with rise in temperature. The
observed decrease in dc resistivity with temperature is normal behavior for semiconductors
which follows the Arrhenius relation. It was observed that the samples having higher values of
resistivity also possessed higher activation energy. The saturation magnetization was observed to
decrease with yttrium contents which are due to redistribution of cations on the tetrahedral and
octahedral sites. The coercivity was observed to increase with yttrium contents. The smaller
grains may obstruct the domain wall movement. As a result, the values of initial permeability (
μ i′ ) decreased from 110 to 35, 27 to 6 and 185 to 87 at 1 MHz in NiY-, MgY- and NiZnY-
ferrites respectively. The values of magnetic loss tangent decreased from 0.23 to 0.03, 0.04 to
0.007, 1.2 to 0.41 in NiY-, MgY- and NiZnY-ferrites respectively. This may be attributed to the
increase in resistivity that reduces the eddy current loss. The frequency dependent behaviors of
dielectric constant follow the Maxwell–Wagner’s interfacial polarization in accordance with
Koops phenomenological theory. The introduction of yttrium ions decreases the dielectric
constant and dielectric loss tangent (tan δ). The results obtained are of great interest for the
development of modified spinel ferrites for various industrial applications.