Growth of vanadium oxides nanostructures by chemical vapour deposition
Among the transition metal oxides, vanadium oxide (V2O5) has attracted attention in various industrial applications such as electrochromic, optical switching and energy storage devices. However, the commercial application of V2O5 in energy storage devices is limited due to its poor cycling stability...
Saved in:
| Main Author: | |
|---|---|
| Other Authors: | |
| Format: | Theses and Dissertations |
| Language: | English |
| Published: |
2015
|
| Subjects: | |
| Online Access: | https://hdl.handle.net/10356/62536 |
| Tags: |
Add Tag
No Tags, Be the first to tag this record!
|
| Institution: | Nanyang Technological University |
| Language: | English |
| Summary: | Among the transition metal oxides, vanadium oxide (V2O5) has attracted attention in
various industrial applications such as electrochromic, optical switching and energy
storage devices. However, the commercial application of V2O5 in energy storage
devices is limited due to its poor cycling stability, Li ion diffusion and electric
conductivity. Two-dimensional (2-D) nanostructures have demonstrated better stability,
more active sites for lithium insertion/deinsertion than zero-dimensional and onedimensional (1-D) structure, making them attractive in energy storage devices. The
formation of V2O5 nanosheets have been challenging because V2O5 tends to grow into 1-
D structure because of its preference to grow in [010] direction. Although several works
have been done on the formation of nanosheets, the synthesis requires long duration (~12-
48 hours).
This thesis investigates the growth of 2-D V2O5 nanostructures arrays on various
current collectors such as aluminium, nickel and stainless steel using chemical vapour
deposition process. This includes various approaches to form 2-D V2O5 nanostructures
arrays on current collectors, namely self-growing and self/wet-etching.
Aluminium foil was wet etched to create a 2-D hierarchical current collector using
lithium hydroxide alkaline solution. Al foil etched with 0.15 M LiOH solution shown
larger amount of nanosheets and etched surface area among various concentrations tested.
V2O5 thin film grown on etched Al foil has an average particle size of ~205, ~121, ~70
and ~24 nm when placed with a substrate distance of 7, 10, 13, 25 cm away from the
center of the tube furnace. The growth of the nanoparticles thin film follows the island
growth mechanism where the adatom adsorbed on the nuclei. Supercapacitor
measurements were made suggests that V2O5 on hierarchical Al perform better with Cs of
~289 F g-1 and retention of ~91% and V2O5 on untreated Al foil with Cs of ~152 F g-1 and
retention of ~76% after 1000 cycles at a rate of 5 A g-1 in 1 M LiClO4 in PC. The
capacitance of the electrode is also dependent on the thickness or mass loading of the film.
By increasing the amount of V2O5 deposition, the Cs is reduced from ~295 to ~189 F g-1.
v
Catalyst-free growth of nanowires and nanosheets were synthesized directly on Ni
foam. V2O5 nanowire averages a diameter of ~126 nm and a few micrometers in length.
The growth is suggested to follow the vapour-solid growth and the formation is due to the
anisotropic growth as [010] is the fastest growth direction. Interconnected V2O5 nanosheet
arrays on Ni foam have an average diameter of ~13.5 µm and thickness of ~198 nm. The
growth of nanosheets arrays on Ni foam is due to the high substrate temperature which
leads to fast diffusion of adatoms and crystal growth rate, and allows side deposition,
forming the nanosheets structure. V2O5 nanosheets on Ni foam perform better with Cs of
~1081 F g-1 and retention of ~96% and V2O5 nanowire on Ni foam with Cs of ~833 F g-1
and retention of ~75% after 1000 cycles at a rate of 2 A g-1 using 2 M KOH.
Vanadium deposition on stainless steel foils results in the formation of amorphous
iron vanadate (FeVO4) nanosheets arrays. The width and thickness of nanosheets are ~100
– 500 nm and 10 – 40 nm, respectively. The growth of the FeVO4 thin film initiates from
the oxidation of stainless steel foil forming Fe2O3 on the surface and interacting with the
vanadium precursor. Annealing the sample to improve crystallinity in Ar atmosphere
leads to the collapse of nanosheet arrays and evaporation of vanadium from the as-grown
film. The electrochemical property of the as-grown film achieved an initial discharge
capacity of 1693 mAh g-1 on the initial cycle at a rate of 0.2 A g-1 (0.15 C). The
Coulombic efficiency is ~73% for the first cycle and shows a reversible capacity of 1237
mAh g-1 after 100 cycles.
The formation of two-dimensional nanosheets arrays on various current collectors
have shown good performance and improved cyclic stability. Various morphologies such
as nanoparticles thin film and nanowires were also synthesized, demonstrating the
flexibility of chemical vapour deposition process. |
|---|