posted on 2013-08-01, 13:26authored bySusan J. Stott
This thesis is concerned with the deposition of nanoparticle films onto boron-doped
diamond and tin-doped indium oxide (lTO) surfaces and the characterisation of the
films using electron microscopy, powder diffraction methods and quartz crystal
microbalance (QCM) data. The redox behaviour of the porous films was examined
using cyclic voltammetry in various media to investigate potential electroanalytical
applications.
TiOz (anatase) mono-layer films were immobilised onto an inert boron-doped
diamond substrate. Cyclic voltammetry experiments allowed two distinct steps in
the reduction - protonation processes to be identified that are consistent with the
formation of Ti(III) surface sites accompanied by the adsorption of protons.
Preliminary data for electron transfer processes at the reduced TiOz surface such as
the dihydrogen evolution process and the 2 electron - 2 proton reduction of maleic
acid to succinic acid are discussed.
Novel multi-layer TiOz films were deposited with a variety of organic binder
molecules onto ITO substrates. The redox reactivity of Cuz+ with 1,4,7,10-
tetraazacyclododecane- 1,4,7, IO-tetrayl- tetrakis (methyl-phosphonic acid) in
solution and immobilised on an electrode surface are investigated. The influences of
film thickness, scan rate, and pH on the electrochemistry of immobilised
pyrroloquinoline quinone was investigated with two possible electron transport
processes observed. The thickness of TiOz phytate films was found to change the
shape of the resulting cyclic voltammograms dramatically. Computer simulation
and impedance spectroscopy allowed insights into the diffusion of electrons to be
obtained. 1, 1 ~Ferrocenedimethanol was employed as an adsorbing redox system to
study the voltammetric characteristics of carboxymethyl-y-cyclodextrin films and
evidence for two distinct binding sites is considered. The apparent transport
coefficients for dopamine and Ru(NHJ)6J+ are estimated for TiOz Nafion® films.
The electrochemical processes in biphasic electrode systems for the oxidation of
water-insoluble N,N-didodecyl-N;N~diethyl-benzene-diamine (DDPD) pure and
dissolved in di-(2-ethyl-hexyl)phosphate (HDOP) immersed in aqueous electrolyte
media are described. Transfer of the anion from the aqueous electrolyte phase into
the organic phase accompanies the oxidation of pure DDPD. In the presence of
HOOP, oxidation is accompanied by proton exchange. The electrochemically driven
proton exchange process occurs over a wide pH range. Organic microdroplet
deposits of OOPD in HDOP at basal plane pyrolytic graphite electrodes are studied
using voltammetric techniques and compared to the behaviour of organic
microphase deposits in mesoporous Ti02 thin films. Two types of Ti02 thin film
electrodes were investigated, (i) a 300-400 nm film on ITa and (ii) a 300-400 nm
film on ITa sputter-coated with a 20 nm porous gold layer. The latter biphasic
design is superior.
Titanium carbide (TiC) nanoparticies were deposited onto ITa electrodes. Partial
anodic oxidation and formation of novel core-shell TiC-Ti02 nanoparticies was
observed at applied potentials positive of 0.3 V vs. SCE. Significant thermal
oxidation of TiC nanoparticies by heating in air occurs at 250 °c leading to coreshell
TiC-Ti02 nanoparticies, then Ti02 (anatase) at ca. 350 °c, and Ti02 (rutile) at
temperatures higher than 750 °c. The electrocatalytic properties of the core-shell
TiC-Ti02 nanoparticulate films were surveyed for the oxidation of hydroquinone,
ascorbic acid, dopamine and nitric oxide (NO) in aqueous buffer media.
Mono- and multi-layer Ce02 deposits on ITa are shown to be electrochemically
active. A reduction assigned to a Ce(IV/III) process has been observed and followup
chemistry in the presence of phosphate discovered. The interfacial formation of
CeP04 has been proven and effects of the deposit type, pH and phosphate
concentration on the process analysed. The electrochemistry of multi-layer Ce02
nanoparticulate films in organic solvent is shown to be more stable.