Browsing by Author "Mombeshora, Edwin Tonderai."

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The physicochemical properties of carbon nanotube-titania nanocomposite for light harvesting.
(2014) Mombeshora, Edwin Tonderai.; Nyamori, Vincent Onserio.; Ndungu, Patrick Gathura.
Nanocomposites for dye-sensitised solar cells (DSSCs) were synthesised from ultrasonic acid-treated multiwalled carbon nanotubes (MWCNTs) and titania precursors by means of sol-gel and chemical vapour deposition (CVD) processes. The wt.% of MWCNTs in nanocomposites were varied from 2 to 98. Physicochemical properties investigation forms the core of the study. Hence, nanocomposites were thoroughly characterised by means of thermogravimetric analysis (TGA), scanning electron microscopy (SEM), transmission electron microscopy (TEM), high resolution transmission electron microscopy (HRTEM), electron dispersive X-ray spectroscopy (EDX), Raman spectroscopy, Fourier transformation infra-red spectroscopy (FTIR), textural characteristics, inductively coupled plasma optical emission spectroscopy (ICP-OES), photoluminescence (PL) and powder X-ray diffraction (XRD) techniques. Nanocomposites were used as photoanode in assembled DSSCs. The gel electrolyte was polyvinyl acetate (PVAc) doped with LiI. Aluminium was the photocathode. The DSSCs were tested for their performance by illuminating them in a solar simulator device. Characteristic hollow MWCNTs morphology with titania particulates was obtained. Both synthetic methods coated small diameter MWCNTs well. EDX spectra showed titania and carbon peaks. The ICP-OES data correlated with TGA in that residual wt.% values were within the expected ranges. Defects from acid treatment lowered thermal stability of pristine MWCNTs from 640 °C to 625 °C. Ti-O-C bond (ca. 1110 cmˉ¹) and anatase form of titania (ca. 669, 577 and 411 cmˉ¹) were observed. Raman spectroscopy showed Eg, A₁g + B₁g₍₂₎ and B₁g₍₂₎ modes of anatase titania at ca. 630, 514 and 396 cmˉ¹ respectively. ID/IG trends indicate that titania reduced defects in MWCNTs. MWCNTs in nanocomposites from the CVD method had fewer defects, highly thermally stable and more uniformly coated, more crystalline, more porous and had smaller surface areas than sol-gel prepared nanocomposites. Nanocomposites had lower eˉ/h⁺ recombination and band gap energy than titania. The optimum MWCNTs wt.% in DSSCs was 15% and CVD nanocomposites were 900% more efficient. From this work, ideal nanocomposites physicochemical properties for DSSCs application include uniform morphology, a defect-free nature, crystallinity, large pore size and volume, and existence of chemical bonds between components. Other factors rather than band gap engineering such as absorption properties of DSSC components also affect DSSC capabilities. Also, the high eˉ conductivity nature of MWCNTs interferes with eˉ transport from the nanocomposites to the counter electrode at high MWCNTs wt.%.
Synthesis and functionality of boron-, nitrogen- and oxygen-doped shaped carbon-based nanomaterials and titania nanocomposites in electrochemical capacitors
(2017) Mombeshora, Edwin Tonderai.; Nyamori, Vincent Onserio.
Energy is a global fundamental sector and major concerns are inclusive of; making renewable power economical, reliable and accessible to all, maintain and improve power quality, voltage and frequency, amongst others. There is need for development of intelligent energy storage systems (ESS) that maximise and provides durable storage of electrical power generated. This is a suitable approach towards reducing gas emissions, lowering electricity bills, meet power needs at any time and for lowering excess power fluctuations. Much advancement is required on ESS to shift their optimum working regions towards preferred limits with both high justifiable power and energy. Advancement of ESS need to be sought through developing effective electrode materials. Shaped carbon nanomaterials (SCNMs) are suitable for ESS in the Smart Grids with potential better cost effective and scalable standards. The investigation of related physicochemical properties of SCNMs, modification of nano-structural parameters and development of appropriate strategies that would enhance their functionality in ESS is key in this regard. In this study, various ESS were reviewed with more focus on development of electrochemical capacitors (ECs) with a bias towards the use of SCNMs as electrodes. The work was aimed at understanding the influence of reagent ratio in the physicochemical properties of N-doped multiwalled carbon nanotubes (N-MWCNTs) and graphene oxide (GO). Also, it focused on modifying the functionality of MWCNTs, N-MWCNTs and reduced graphene oxide (RGO) in ECs via introduction and control of heteroatoms such as nitrogen and its functional moieties or introduction of oxygen-containing groups. Thirdly, the work investigated the effect of composite synthesis on the performances of individual components via control of wt.% ratios. Characterisation techniques used include transmission and scanning electron microscopies, atomic force microscopy, textural characteristics, thermogravimetric analysis, elemental analysis, cyclic voltammetry, electrochemical impedance spectroscopy, X-ray photoelectron spectroscopy, X-ray diffraction, ultraviolet-visible spectrophotometry, Raman and Fourier transform infra-red spectroscopies. N-MWCNTs were synthesized from N,N’-dimethyl formamide and acetonitrile as sp3 and sp hybridized nitrogen sources, respectively, as materials for ECs. The combination of ferrocene carboxaldehyde, N,N’-dimethyl formamide and acetonitrile in N-MWCNTs synthesis was a novel approach. Mixing the sp3 and sp sources in 1:3 ratio enhanced nitrogen content to 9.38% from that of both sp3 (5.87%) and sp (3.49%). The physical properties such as number of concentric shells were tailored by varying synthesis temperature. Pyrrolic N-doping was achieved as the main constituent of nitrogen moieties. Furthermore, GO was synthesized as a preliminary step for further N-doping. The effect of graphite: Na2NO4 reagent ratio in the synthesis of GO was studied to elucidate the influence of the initial step in GO synthesis, via modified Hummer’s method, and to develop novel strategies towards controllable products. The physicochemical properties such as content of oxygen-containing groups on GO and the surface areas were increased from 0% and 2 m2 g-1 to 30% and 188 m2 g-1, respectively, by increasing the proportion of Na2NO4 in reagents. The manipulation of the initial step was a novel means of tailoring the associated physicochemical properties of GO. Also, this study determined, for the first time, the most effective group one sulfate electrolyte at fixed concentrations. This aided the selection of the electrolyte used in the application of the SCNMs in this thesis. Oxygen moieties were introduced, by ultra-sonic waterbath treatment, onto MWCNT surfaces using various reagents namely; HCl, HNO3, H2O2 and HNO3/ HCl solutions. The study highlighted how the various reagents, commonly used to purify MWCNTs after synthesis, modify associated physicochemical properties and alter charge storage characteristics. Oxygen-containing groups increased capacitance of pristine MWCNTs and introduced pseudo charge storage mechanism via oxygen functionalities. HNO3 treated MWCNTs had a 77- and 2.5-fold upgrading from pristine using Li2SO4 and Na2SO4, respectively, whilst HNO3/ HCl was the best, 5 times better, in K2SO4. The oxygen-modified MWCNTs performance was highest and of best quality in Na2SO4. The effectiveness of common GO reductants, namely; ascorbic acid, hydrazine hydrate and sodium borohydride were practically investigated. This was done to select a reductant for the current work. This study also provided a viable novel chemical tuning approach for nitrogen moieties and content as well as to introduce boron, with sodium borohydride. Thirdly, under this particular study, the effect of heteroatoms, boron and nitrogen, as well as nitrogen moieties on physicochemical characteristics of RGO was also explored. Hydrazine hydrate was the most effective reductant and was associated with highest surface area and N-content of 390.55 m2 g-1 and 4.07 at.%, respectively. The nitrogen groups of RGO reduced by means of ascorbic acid, hydrazine hydrate and pristine were pyrrolic, pyridinic and sp3 N-C, respectively. N- doped RGO, particularly pyrrolic moieties, were 76-fold better than B-doped. A further iii iv thermal reduction, of RGO from hydrazine hydrate, increased surface area from c.a. 391 to c.a. 600 m2 g-1 at 750 ℃. The effect of oxygen-containing groups was then investigated in composites of titania with GO, RGO and cellulose reduced graphene oxide (CRG). The wt.% ratios of titania were varied; i.e., 5, 10, 20 and 40%. Based on earlier deductions in this thesis, reductant chosen was hydrazine hydrate. Titania enabled better exfoliation of GO but at higher wt.%, it culminated in larger agglomerates which in turn increased diffusion path-length. RGOTi at 5 wt.% titania increased surface area from 136.89 to 434.24 m2 g-1. The study generally showed that capacitance was better at lower wt.% titania in RGOTi and that cellulose surface area increase was outweighed by associated insulating effect. The present data infers that the impact of oxygen moieties on capacitance of SCNMs was subject to specific structures; MWCNTs, GO and RGO. Capacitance of titania and GO were improved by composite synthesis. Graphenated N-MWCNTs were targeted, as a means, to lessen agglomeration, without the use of surfactants, and to generate 3-D scaffolds for better electrical conductivity channels. Also, better physicochemical characteristics for higher capacitance were obtained via sol-gel than CVD method. The ratios of sp3- and sp-hybridized nitrogen in reagent mixtures, in this thesis, was effectively used to tune the composition of pyrrolic nitrogen moieties. Pyrrolic composition of N-MWCNTs was uniquely aimed because studies of typical moieties on RGO deduced pyrrolic to be better than pyridinic groups. The increase of pyrrolic nitrogen composition; 35, 45 and 60%, culminated in capacitance deterioration. Composite synthesis reduced Warbug length and amplified associated capacitance. The physicochemical properties of RGO, GO, MWCNTs and N-MWCNTs were positively tuned from reagent ratios, conditions and composite syntheses. The conjectured strategies could modulate their overall capacitance via manipulation of heteroatom content and functional groups, amongst others listed herein. Several traits that linked physicochemical properties and capacitance were successfully elucidated. This affirms the hypothesized potential of SCNMs in ESS through understanding and control of both nano-structural parameters and physicochemical properties.
Synthesis and functionality of boron-, nitrogen- and oxygen-doped shaped carbon-based nanomaterials and titania nanocomposites in electrochemical capacitors.
(2017) Mombeshora, Edwin Tonderai.; Nyamori, Vincent Onserio.; Ndungu, Patrick Gathura.; Jarvis, Alan Lawrence Leigh.
Abstract available in PDF file.