Development of metal oxide nanostructures incorporated with carbon matrix for electrochemical applications / Numan Arshid
Over the last few decades, nanomaterials have found prodigious potential in various applications of different research fields. Although the metal oxide frame work is not a new class of nanomaterials yet its potential is not explored extensively, especially for electrochemical applications. One of...
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| Format: | Thesis |
| Published: |
2018
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| Online Access: | http://studentsrepo.um.edu.my/8453/2/All.pdf http://studentsrepo.um.edu.my/8453/6/numan.pdf http://studentsrepo.um.edu.my/8453/ |
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| Summary: | Over the last few decades, nanomaterials have found prodigious potential in various
applications of different research fields. Although the metal oxide frame work is not a
new class of nanomaterials yet its potential is not explored extensively, especially for
electrochemical applications. One of the most significant research motivations for metal
oxide frame works come from their tunable morphology, porosity, rigidity/flexibility,
variety and facile design which make them capable of using in variety of advanced energy
conversion, energy storage and electrochemical sensing devices. However, unsupported
metal oxide nanostructures suffers from particle aggregations which lead to decrease their
electrochemical surface area. In this work, one step hydrothermal route was used to
develop binary nanocomposite of metal oxide (Co3O4) and carbonaceous matrix such as
graphene, multiwall carbon nanotubes (MCNTs). The first system, binary composite of
reduced graphene intercalated with cobalt oxide (Co3O4) nanocubes was synthesized and
the contents of Co3O4 precursor were optimized with respect to fixed amount of reduced
graphene oxide (rGO). The rGO−Co3O4 nanocubes was used for supercapacitor
application. It was found that with 0.5 mmol of cobalt precursor (A2) gave the highest
specific capacity (125 Cg-1) in three electrode cell system. Same nanocomposite was used
to fabricate rGO−Co3O4 nanocubes//activated carbon hybrid supercapacitor and the
maximum energy and power density was found to be 7.75 Wh.k-1 and 996.42 W.kg-1,
respectively. In second system, composite of rGO−Co3O4 nanograins was optimized by
varying the contents of rGO with respect to the fixed concentration of Co3O4 precursor.
The performance of rGO−Co3O4 nanograins was evaluated for electrochemical sensing
of dopamine. The nanocomposite rGO−Co3O4 (B3) with 9.1 wt. % of rGO was optimized on the basis of oxidation current of dopamine. The B3 modified glassy carbon electrode
gave 0.277 μL (S/N=3) limit of detection for dopamine in the linear range of 1−30 μL.
The performance of B3 modified GCE was also satisfactory in real time urine sample and
in the presence of physiological interfering analytes. In the last system, Co3O4 nanocubes
were fabricated with MWCNT and the contents of MWCNT with respect to the fixed
amount of cobalt precursor were optimized. The MWCNT−Co3O4 nanocube was used for
supercapacitor and electrochemical sensing of dopamine application. In both
applications, MWCNT−Co3O4 nanocubes (C4) with 16 wt. % of MWCNT demonstrated
excellent electrochemical performance compared to its counterparts. The maximum
specific capacity was 142 Cg-1 using three electrode cell system. The highest energy
density was found to be 19.28 Wh.kg-1 at power density of 309.85 W.kg-1. The optimized
nanocomposite (C4) also showed excellent electrochemical performance for dopamine
detection. The limit of detection is found to be 0.176 μL in the linear range of 1−30 μL.
However, MWCNT−Co3O4 nanocube showed poor selectivity towards dopamine
detection. Overall, MWCNT−Co3O4 nanocubes gave better performance for hybrid
supercapacitor compared to rGO−Co3O4 nanocubes in terms of specific capacity and
energy density. However, rGO−Co3O4 nanograins endowed good sensing capability for
dopamine detection in terms of selectivity compared to MWCNT−Co3O4 nanocubes. This
work embark the frontiers of carbonaceous materials for electrochemical applications. |
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