Superhydrophilic TiO2 nanomaterials for efficient oil-water separation
The rapid growth of industrial activities and occurrences of environmental pollution such as contaminated oil spill evoke situations leading to water source contamination. Furthermore, surfactant-containing oil-water mixtures tend to emulsify the oil into small and stable droplet that are diff...
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| Format: | Theses and Dissertations |
| Language: | English |
| Published: |
2017
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| Subjects: | |
| Online Access: | http://hdl.handle.net/10356/72439 |
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| Institution: | Nanyang Technological University |
| Language: | English |
| Summary: | The rapid growth of industrial activities and occurrences of environmental pollution
such as contaminated oil spill evoke situations leading to water source contamination.
Furthermore, surfactant-containing oil-water mixtures tend to emulsify the oil into
small and stable droplet that are difficult to be separated from water. Currently,
conventional techniques have shown their incapability of tackling such problem.
Therefore, significant attention has been drawn to introduce advance materials or
techniques that are suitable for effective oil-water separation process. This thesis
explores the feasibility of TiO2-based material and its derivatives in separating oil
from water.
In general, the TiO2-based materials reported in this thesis are fabricated using
hydrothermal method, and the membranes were synthesized via a 2 step process
which include filtration and hot pressing. TiO2 materials has been the most promising
candidate for oil-water separation membranes due to its intrinsic superhydrophilic
and underwater superoleophobic properties. For the initial part of the work, the
pristine TiO2 nanowire was investigated for its oil-water separation ability with the
aid of a flexible scaffold. In this study, it is the first time that we fabricated a novel
micro/nanowire hierarchical membrane with flexible, self-cleaning and underwater
superoleophobic properties for efficient oil-water separation under vacuum filtration.
This novel membrane composed of ultralong copper microwires (MW) and
functional TiO2 nanowires (NW). The ultralong copper microwires act as a scaffold,
as well as providing mechanical flexibility for the membrane, which allow it to be
operated under vacuum-driven condition. Meanwhile, underwater superoleophobic
TiO2 nanowires membrane provides nano-scale pore size, ensuring the filtration of
smaller oil droplets with droplet size> 600nm under vacuum condition. Moreover,
the possession of the self-cleaning function of TiO2 nanowires allows the degradation
of foulants and contaminants under UV irradiation, which promote the facile recovery
of the used membrane.
In order to further understand the oil-water separation efficiency and photocatalytic
effect corresponding to the TiO2 nanomaterial morphology, a comparative study of
self-cleaning ability and oil-water separation efficiencies of 1D TiO2 nanostructure with that of 3D TiO2 nanostructure was conducted. Various TiO2 membranes formed
by different nanostructures including 1D TiO2 nanotube, 1D TiO2 nanowire and 3D
nanosheet-decorated TiO2 nanowire hierarchical structure were synthesized and
compared. The oil-water separation results showed that the three membrane portrayed
excellent oil-water separation ability due to the formation of water layers represented
by their high water capture percentage (WCP). Studies from the self-cleaning
experiment indicated that TSW (3D nanosheet-decorated TiO2 nanowire) membrane
has the shortest time to self-clean the oleic acid accumulated on its surface and
simultaneously recovers its superhydrophilicity property. In addition, the results for
photodegradation activity showed that 3D nanosheet-decorated TiO2 nanowire has
the highest photodegradation efficiency among the investigated TiO2 nanostructures
to eliminate intermediate organic compounds. This is attributed to its high light
harvesting capacity resulting from the multiple reflections of incident light and
superior electron collection properties due to the hierarchical structure. Essentially,
this study paves way for enhancing oil-water separation performance of other
photocatalysts through the modification of its nanostructure.
To reinforce the TiO2 nanomaterials with excellent oil-water separation ability,
photocatalytic properties and mechanical flexibility, Fe2O3 nanoneedles were grown
uniformly on TiO2 nanowire substrate to provide the clinching effect once compacted
together. Hence, the subsequent study introduces a hierarchically nanostructure
multifunctional TiO2/Fe2O3 composite membrane, which is capable of separating
surfactant-stabilized oil-water emulsions with high separation efficiency. The
experimental results showed that the membrane is capable of removing droplet size
as small as 400nm. The high oil rejection rate is contributed by the acquisition of an
interconnected delicate network and underwater superoleophobic interface.
Meanwhile, its self-cleaning function promote the facile recovery of the contaminated
membrane. Furthermore, the mechanical flexible characteristic of the multifunctional
TiO2/Fe2O3 composite membrane widens its applicability in industrial employment.
The separation performance of multifunctional TiO2/Fe2O3 composite membrane was
further evaluated by operating the membrane in a two-step treatment process. The asprepared
membrane was examined for its ability in photodegrading dye contaminants
effectively without affecting its oil-water separation efficiency. Methyl blue (MB), Rhodamine B (RhB) and acid orange (A07) aqueous solution were the three types of
common pollutants employed in this study. The results showed that the TiO2/Fe2O3
composite membranes demonstrated excellent oil-water separation ability under
vacuum filtration process even after photodegrading the various types of dye
contaminant. Ultimately, the introduction of this membrane provides an opportunity
to eliminate dye contaminants and separating oil from water effectively.
In sum, the results gathered from this thesis illustrated that TiO2-based membrane can
be regarded as a practical option in managing polluted surfactant-stabilized oily
wastewater. |
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