dc.description.abstract |
This thesis constitutes a series of studies on the effects of divalent dopants (A) in place of
Bi in the BiFeO 3 (BFO) multiferroic systems. In addition the effect of film thickness on
the multiferroic properties of BFO has also been investigated. The studies include a
complete set of structural, electronic, magnetic, optical and dielectric studies on the Bi 1-
x Sr x FeO 3-δ
(0 ≤ x ≤ 0.45) and Bi 0.75 A 0.25 FeO 3 (A = Pb, Ba) systems. The studies have been
carried out with the knowledge that substitution of trivalent Bi with the respective
divalent ions will induce changes in the crystalline as well as electronic structures which
in turn would affect the multiferroic properties of the system. Accordingly we find that in
contrast to the weak ferromagnetism of the parent material each of the x=0.25 doped
systems exhibits ferromagnetism at room temperature. A strong correlation is observed
between the magnetic and structural properties, e.g. in the case of Sr doped BFO there is a
strong enhancement of ferromagnetism between x=0.15 and x=0.25 that coincides with a
structural transition from rhombohedral to cubic phase (R3c → Pm-3m) at x=0.25.
Magnetic moment was observed to increase with increase in the radius of A-site ion being
largest for the Ba doped system. Further insight into the origins of the ferromagnetism
enhancement was obtained through Mössbauer measurements which showed that despite
being doped with a divalent ion, the Fe ions in BFO retained their trivalent state. We find
that A 2+ ion substitution at Bi 3+ site results in oxygen deficiency and consequently in a
tetrahedral coordination for some of the Fe−O ions. The role of oxygen vacancies in
promoting ferromagnetism was evident from the decrease in ferromagnetic moment in
oxygen annealed samples. Thus the ferromagnetism in these systems is correlated with
the structural transformation at x=0.25 which tends to destroy/weaken the parent
antiferromagnetic cycloidal spin structure while induced changes in the superexchange
interactions, due to size differences and oxygen vacancy effects, also contribute to the
observed differences. We find a systematic but anomalous decrease in the magnetic
coercivity at low temperatures which is explained in terms of an effective magnetic
anisotropy that includes the effects of magnetoelectric coupling. The dielectric response
for these doped systems depends in general on the structural details as well as the
presence of oxygen vacancies. The Sr x=0.45 composition shows a marked anomaly in
ε(T) which is explained in terms of relaxation effects originating presumably in nanoscale
polar inhomogeneities. The lone pair substituent Pb leads to the largest dielectric
| ixconstant, enhanced magnetization, and large effects on the low-temperature magnetic
hysteresis.
The optical response of multiferroic Bi 1-x Sr x FeO 3 (0 ≤ x ≤ 0.45) samples is studied in the
spectral range from 1 eV to 4 eV by means of UV/Vis spectrometry. Optical response in
the studied spectral range was dominated by two charge transfer transitions and two
doubly degenerate d-d transitions for all samples. The d-d transitions weakened as the Sr
content was increased which is attributed to the transformation of the crystal structure
from rhombohedral to cubic. A red shift in the d-d transition energies was observed with
increasing Sr concentration which is related to an increase in the crystal field strength.
The direct band gap was found to decrease whereas the indirect band gap decreased as the
Sr content is increased from x = 0 to 0.45. The ultimate source of the decrease in the
energy band gap values and the observed red shift in the d-d transition energies is
ascribed to the chemical pressure induced reduction in unit cell volume. For Ba and Pb
doped samples the differences in these optical properties are also consistent with the
associated changes in the unit cell volume.
BFO thin films with thickness increasing from 40 to 480 nm were successfully grown on
LaNiO 3 buffered Pt/Ti/SiO 2 /Si(100) substrate and the effects of thickness evolution on
magnetic and ferroelectric properties have been investigated. All the BFO films exhibited
weak ferromagnetic response at room temperature and saturation magnetization decreases
with increase in film thickness. Well saturated ferroelectric hysteresis loops were
obtained for thicker films; however, the leakage current dominated the ferroelectric
properties in thinner films. The mechanisms for the evolution of ferromagnetic and
ferroelectric characteristics in these films have been discussed. |
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