Abstract:
Among the metal oxides nanomaterials, Zinc oxide (ZnO), Titanium dioxide (TiO2),
Vanadium pentoxide (V2O5) and Tin dioxide (SnO2) are the most promising candidates
for exploring new applications in multiple fields. We have tried to resolve some important
issues related to synthesis and integration of metal oxides nanostructure building blocks
for large scale device applications. This dissertation mainly consists of three major parts,
synthesis, characterization and applications of metal oxides based nanostructures.
Metal oxides and their composites were successfully synthesized by applying
solvothermal/hydrothermal and chemical methods associated with the co-precipitation
technique. Through these techniques, various metal oxide nanostructures including TiO2
microspheres, hierarchical ZnO nanoflowers, plate-like TiO2 nanostructures, V2O5
nanowires, SnO2 cubic microcrystals, and Au/TiO2, (Au, Ag)-ZnO, Ag-TiO2
nanocomposites have been synthesized in controlled experimental conditions.
Subsequently, the crystalinity and the microstructure of the nanomaterials were studied by
X-ray diffraction (XRD), scanning electron microscopy (SEM), transmission electron
microscopy (TEM), high resolution transmission electron microscopy (HRTEM) and
selected area electron diffraction (SAED) technique. The electronic interactions were
confirmed by PL, DRS spectra and XPS studies. The composition and the elemental
analysis were confirmed by EDS. The photocatalytic and electrochemical performances
of these materials were also investigated.
It is found that Au NPs supported TiO2 microspheres exhibit enhanced photocatalytic
activity as compared to pure TiO2 microspheres. Moreover, the electrochemical properties
of Au/TiO2/GCE modified electrode demonstrate the ability to electrocatalyze the
oxidation of hydrogen peroxide and exhibit a rapid and sensitive response towards
glucose detection at the low operating potential. The modified electrode shows a linear
range from 1.0 to 15 mM with reproducible sensitivity of 1350 μA mM-1 cm-2 within less
than 6 sec. The photocatalytic and electrochemical activity of Au/TiO2 composite
provides a new platform for environmental remediation and biomedical applications. The
results demonstrate that Au/TiO2 composite exhibits great prospect for developing
efficient non-enzymatic biosensor and photocatalyst.
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It is observed that the noble metal NPs functionalized ZnO nanoflowers show enhanced
photocatalytic activity than pure ZnO nanoflowers. Au-ZnO exhibits improved catalytic
performance relative to Ag-ZnO. The composite also exhibits a strong interaction
between noble metal NPs and ZnO nanoflowers. PL intensity of Au-ZnO nanocomposite
is lower than Ag-ZnO and pure ZnO which is ascribed to the reduced recombination of
free excitons resulting in enhanced photocatalytic activity. On the other hand, Ag-ZnO
modified glassy carbon electrode shows good amperometirc response to hydrogen
peroxide with linear range from 1 μM to 20 μM, and limit of detection of 2.5 μM (S/N =
3). The sensor also shows high and reproducible sensitivity of 50.8 μA cm-2 μM-1 with
fast response of less than 3 s and good stability as compared to pure and Au-ZnO based
sensors. The results elaborate that noble metal NPs functionalized ZnO nanocomposites
exhibit a great prospect for the development of efficient non-enzymatic biosensor and as
environmental remediators.
Hydrothermally synthesized V2O5 NWs are found single crystalline and orthorhombic.
The room temperature electrical transport properties reveal that complex impedance plane
plot shows two overlapping semicircles which exhibits that the resistance from the
oxygen vacancies and oxygen stoichiometric regions contribute to the overall transport
behavior of V2O5 nanowires. The normalized functions suggest that the long range
movements of the charge carriers are dominant at 100 Hz. The tangent loss (tan δ) is
observed in accordance with the impedance plane plot. The ac conductivity σac shows
substantial increase from 1×10-6—3×10-5 (S/cm2) in the frequency range of 5×103—105
Hz that may be attributed to a large number of charge carriers available for conduction by
hopping.
Structural, photocatalytic and electrochemical properties of hydrothermally synthesized
SnO2 microcrystals have been performed. Microstructural analysis shows that uniform
cubic crystals in the range of microns are formed. It is found that SnO2 microcrystals
exhibit good photocatalytic performance towards RhB degradation. Electrochemical
performance of modified glassy carbon electrode has been investigated using cyclic
voltammetry, galvanostatic charge discharge, and electrochemical impedance
spectroscopy in 1M H2SO4 electrolyte. These measurements reveal that SnO2
microcrystals exhibit excellent capacitive and surface charge storage behavior. The
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measured specific capacitance is found to be strongly dependent on scan rate. The
galvanostatic measurements and cycling stability demonstrate improved stability of the
capacitor. Moreover the EIS measurements confirm the ideal characteristics of the
capacitor. The present study shows that the attractive performance exhibited by SnO2
microcrystals make it promising candidate for high performance supercapacitors.
The photocatalytic activity and the sensing capability of the pure anatase TiO2 and Ag
NPs functionalized TiO2 plate-like nanostructures reveal that Ag-TiO2 nanohybrids
exhibit an excellent photocatalytic activity towards model as well as textile dyes by
completely degrading all the dyes in 15-18 min due to maximum UV absorption, large
specific surface area, stability and catalytic activity of small Ag NPs compared to pure
anatase TiO2 nanostructures. The Ag-TiO2 nanocomposites also show decrease in band
gap energy compared to pure anatase TiO2. On the other hand, Ag-TiO2/GCE modified
electrode shows good amperometirc response towards H2O2 with linear range from 2 to
30 mM and detection limit of 0.5 mM (S/N = 3). The sensor shows high and reproducible
sensitivity of 32 μA mM-1 cm-2 with fast response of less than 3 s and good stability as
compared to pure and TiO2/GCE. All these results illustrate that Ag NPs functionalized
TiO2 nanostructures exhibit a great scenario for the development of efficient nonenzymatic
biosensor and environmental remediator.