2 research outputs found
TiO<sub>2</sub> Nanotubes: Interdependence of Substrate Grain Orientation and Growth Rate
Highly
ordered arrays of TiO<sub>2</sub> nanotubes can be produced
by self-organized anodic growth. It is desirable to identify key parameters
playing a role in the maximization of the surface area, growth rate,
and nanotube lengths. In this work, the role of the crystallographic
orientation of the underlying Ti substrate on the growth rate of anodic
self-organized TiO<sub>2</sub> nanotubes in viscous organic electrolytes
in the presence of small amounts of fluorides is studied. A systematic
analysis of cross sections of the nanotubular oxide films on differently
oriented substrate grains was conducted by a combination of electron
backscatter diffraction and scanning electron microscopy. The characterization
allows for a correlation between TiO<sub>2</sub> nanotube lengths
and diameters and crystallographic parameters of the underlying Ti
metal substrate, such as planar surface densities. It is found that
the growth rate of TiO<sub>2</sub> nanotubes gradually increases with
the decreasing planar atomic density of the titanium substrate. Anodic
TiO<sub>2</sub> nanotubes with the highest aspect ratio form on Ti(−151)
[which is close to Ti(010)], whereas nanotube formation is completely
inhibited on Ti(001). In the thin compact oxide on Ti(001), the electron
donor concentration and electronic conductivity are higher, which
leads to a competition between oxide growth and other electrochemical
oxidation reactions, such as the oxygen evolution reaction, upon anodic
polarization. At grain boundaries between oxide films on TiÂ(<i>hk</i>0), where nanotubes grow, and Ti(001), where thin compact
oxide films are formed, the length of nanotubes decreases most likely
because of lateral electron migration from TiO<sub>2</sub> on Ti(001)
to TiO<sub>2</sub> on TiÂ(<i>hk</i>0)
Electrode Reaction Mechanism of Ag<sub>2</sub>VO<sub>2</sub>PO<sub>4</sub> Cathode
The high capacity of primary lithium-ion
cathode Ag<sub>2</sub>VO<sub>2</sub>PO<sub>4</sub> is facilitated
by both displacement
and insertion reaction mechanisms. Whether the Ag extrusion (specifically,
Ag reduction with Ag metal displaced from the host crystal) and V
reduction are sequential or concurrent remains unclear. A microscopic
description of the reaction mechanism is required for developing design
rules for new multimechanism cathodes, combining both displacement
and insertion reactions. However, the amorphization of Ag<sub>2</sub>VO<sub>2</sub>PO<sub>4</sub> during lithiation makes the investigation
of the electrode reaction mechanism difficult with conventional characterization
tools. For addressing this issue, a combination of local probes of
pair-distribution function and X-ray spectroscopy were used to obtain
a description of the discharge reaction. We determine that the initial
reaction is dominated by silver extrusion with vanadium playing a
supporting role. Once sufficient Ag has been displaced, the residual
Ag<sup>+</sup> in the host can no longer stabilize the host structure
and V–O environment (i.e., onset of amorphization). After amorphization,
silver extrusion continues but the vanadium reduction dominates the
reaction. As a result, the crossover from primarily silver reduction
displacement to vanadium reduction is facilitated by the amorphization
that makes vanadium reduction increasingly more favorable