Two
kinds of nanosized ferrite systems have been prepared: MFe2O4 nanoparticles and MFe2O4/SiO2 (M: Co, Ni) nanocomposites with different
ferrite particle sizes. Magnetic measurements have been done for both
ferrite systems in the 5–700 K temperature range, and the silica
matrix effect on the magnetic behavior has been studied. Whereas CoFe2O4 samples are characterized by high anisotropy
values, NiFe2O4 particles seem to be magnetically
soft, which may favor the dipolar interactions. The silica matrix
avoids all kinds of particle interactions that modify the magnetic
behavior. Therefore, in 2–5 nm embedded Co-ferrite particles,
a decreasing H
C value with the increasing
particle size is not observed. This almost constant H
C value indicates that interactions between surface spins
of different particles are absent for this particle size range. In
the case of Ni-ferrite particles, the dipolar interactions between
bulk particle moments are minimized due to the presence of the SiO2 matrix.
NiFe2O4 and ZnFe2O4 nanoparticles have been prepared encased in the MCM (Mobile Composition of Matter) type matrix. Their magnetic behavior has been studied and compared with that corresponding to particles of the same composition and of a similar size (prepared and embedded in amorphous silica or as bare particles). This study has allowed elucidation of the role exerted by the matrix and interparticle interactions in the magnetic behavior of each ferrite system. Thus, very different superparamagnetic behavior has been found in ferrite particles of similar size depending on the surrounding media. Also, the obtained results clearly provide evidence of the vastly different magnetic behavior for each ferrite system.
ZnFe2O4 and NiFe2O4 particles
ranging from 5 to 8 nm have been prepared inside the channels
of SBA-15 mesoporous material and nanowires were recovered after dissolving
the silica matrix. For both ferrite compositions a hardening of the
magnetic behavior has been obtained when using the mesoporous matrix.
Thanks to the comparison of the magnetic behavior of the nanoparticles
when contained and not in the matrix, it was possible to elucidate
not only the matrix effect but also the kind of interparticle interactions
depending on the ferrite composition. Thus, nickel ferrite particles
are characterized by intense dipolar interactions that are responsible
for the so high superparamagnetic response and that can be avoided
by matrix effects only at high temperatures. On the contrary, the
inherent low-intense dipolar interactions of the zinc ferrite system
lead it to present lower superparamagnetic moments, and in the case
of encapsulated particles, the superparamagnetic behavior would correspond
to almost not-interacting particles. In addition, interactions occurring
between surface spins of different particles are more visible in zinc
ferrite system as consequence of its so low intense dipolar interactions
and are prevented thanks to the use of the matrix.
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