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Production of ion exchange membrane for hydrogen fuel cellMufula, Alain Ilunga January 2017 (has links)
A thesis submitted to the Faculty of Engineering and the Built Environment,
University of the Witwatersrand, Johannesburg, in fulfillment of the
requirements for the degree of Doctor of Philosophy in Engineering.
Johannesburg, 2017 / Among of the components of the fuel cell, the polymer electrolyte membrane is
critical to the performance and life time of the cell. Over the years the mechanical
properties of the membrane, water management have tended to limit its wide
spread commercialization as an alternative source of the renewable energy for
portable power units. Fuel cell continues to attract extensive research interest as
potential source of renewable energy. This work focuses on the production of ionexchange
membrane (IEM) for hydrogen fuel cell, using cheap and locally
available starting materials. The polystyrene-butadiene rubber (SBR) of different
styrene and butadiene compositions, have been explored for functionality in fuel
cell application. The production process was conducted in three stages: the first
stage involved hydrogenation process followed by sulfonation process. The
second stage entailed the production of carbon nano-spheres for the blending in
the hydrogenated sulfonated polystyrene-butadiene rubber. The blending was also
done between hybrid nanoparticles and hydrogenated sulfonated polystyrenebutadiene
rubber. The third stage was the casting in thin film of blended solutions
employing the evaporative method and the use of casting tape machine technique.
The thin film was later on characterized and tested in a single fuel cell stack.
Controlled hydrogenation of SBR employing catalytic method was achieved with
maximum degree of hydrogenation in the range of:
90 – 92% for SBR with 23.5% styrene content and for SBR 25% styrene
content
76 – 80% for SBR with 40% styrene content and
82 – 92% for SBR with 52% styrene content.
The optimum conditions of this process were obtained using the Design of
Experiments.
SBR was also hydrogenated using a photocatalytic method and the percentage of
hydrogenation for all SBR compositions used was found in the range between 60
and 74%. The hydrogenation results using the catalyst were higher compared to
those obtained with the photocatalytic method. Therefore they were used to
develop the kinetic model for prediction of hydrogenation process. Langmuir –
Hinshelwood models were reviewed in this project as they explain these
heterogeneous catalytic processes. Data from the kinetic tests were fitted to
Langmuir – Hinshelwood models and reaction constants were found in the range
between 0.445 h-1 and 0.610 h-1 for the reaction temperature between 20 and
30°C.
The hydrogenated SBR of different compositions were effectively sulfonated with
chlorosulphonic acid employed as first sulfonating agent of concentrations 0.15,
0.175 and 0.25M for SBR 23.5 and 25% styrene content, for SBR 40% styrene
content and for SBR 52% styrene content, respectively. The degree of sulfonation
was found in the range between 56 and 72% depending on the rubber
composition. Trimethylsilyl chlorosulfonate used as the second sulfonating agent
was like wise attached to the same polymer back bone and the degree of
sulfonation was between 59 and 74% depending on the rubber’s styrene content.
Non-conductive carbon nanospheres (CNS) of uniform size of about 46 nm were
produced employing the non-catalytic chemical vapour deposition method at
1000°C. Acetylene and argon were respectively used as carbon source and carrier
gas, in a reactor of 16 mm in diameter. Successful blending of 4 wt%
nanoparticles and hydrogenated sulfonated styrene butadiene solution was
accomplished by magnetic stirring technique combined with ultrasonication at
60% amplitude. The blended solution was casted to produce a thin film membrane
of 156 μm thickness. Further the tensile strength test of the membranes has shown
an increase in Young’s Modulus by 72-120% for all the rubbers. This test was
done using TA.XTplus, Texture Analyser machine. The water uptake increment
was in the range of 20-27% and thermal stability in the range of 2-20% depending
on the rubber composition. Purchased electrodes from FuelCellsEtc (USA), were
pasted on both sides of the membranes by the means of hot press at 125oC for
about 5 minutes at a pressure of 40 kPa. The Membrane Electrode Assembly
(MEAs) fabricated were tested in the fuel cell stack. The highest power density of
approximately 85mW/cm2 was obtained for 52% styrene nanocomposite
membrane with 4% hybrid nanoparticles at the current density of 212.41mA/cm2
and the efficiency was between 41 and 43%. MEA fabricated with Nafion112
membrane was tested and yielded the open cell voltage of 0.79V, power density
of about 77.34mW/cm2 and efficiency of 45%. Results obtained disclose that the
MEA with nanocomposites based SBR 52% styrene composition yielded higher
power density and higher voltage than the one with Nafion 112 which is one of
the fuel cell membranes available on the market. The results obtained revealed
that the nanocomposite membranes with 4% hybrid nanoparticles (CNS + SiO2)
had higher voltage than the one with 4% CNS. These optimum conditions
obtained in this work may be adopted for a typical continuous production of the
membrane for hydrogen fuel cell. / MT2018
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Water treatment by reverse osmosis.Trivedi, Chandra Shekhar. January 1971 (has links)
No description available.
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Physiological effects of salinity on chara corallina /Whittington, John. January 1990 (has links) (PDF)
Thesis (Ph. D.)--University of Adelaide, Dept. of Botany, 1991. / Includes bibliographical references (leaves 197-209).
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Membrane behavior of shales and ionic solutions /Lomba, Rosana Fatima Teixeira, January 1998 (has links)
Thesis (Ph. D.)--University of Texas at Austin, 1998. / Vita. Includes bibliographical references (leaves 232-237). Available also in a digital version from Dissertation Abstracts.
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Electrodialysis in flow injection systems /Hattingh, Cornelius Johannes. January 2000 (has links)
Thesis (Ph.D.(Chemistry))--University of Pretoria, 2000. / Includes abstracts in English and Afrikaans. Includes bibliographical references. Also available online.
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Development of liquid membrane extraction method and ion- imprinted polymers for the analysis and removal of arsenic and selenium in waterMafu, Lihle, D. 25 February 2014 (has links)
M.Sc. (Chemistry) / Please refer to full text to view abstract
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Effect of phenoxy acids and their derivatives on the ionic permeability of bilayer lipid membranesIllangasekare, Malkanthi Paulis 01 January 1979 (has links)
It has been found that the herbicide 2,4-D has the ability to increase the rate of transport of positive ions of several kinds and inhibit the transport of negatively charged tetraphenylborate ions in lipid bilayer membranes. Only the neutral molecules of 2,4-D are transport active. The ionized 2,4-D molecules do not modify the transport of ions, and do not by themselves permeate through lipid membranes. The results suggest that the enhancement of transport of positively charged ions is dominated by the increase of the ion translocation rate constant. It has been shown that membrane transport of negatively charged tetraphenylborate ions is suppressed by 2,4-D. The effect is dominated by the suppression of translocation of these ions across membrane interior, rather than by the decrease of their adsorption at the membrane surface. It has been shown that the enhancement of nonactin-mediated transport of potassium ions by 2,4-D can be accounted for by a simple carrier model. From the changes of kinetic parameters of nonactin-K('+) transport, membrane conductance due to positively charged tetraphenylarsonium ions and also from the changes of membrane conductance and relaxation time constant due to transport of negatively charged tetraphenylborate ions, the changes of the electric potential of the membrane interior have been estimated. The potential of the membrane interior becomes more negative in the presence of 2,4-D and its change is proportional to the aqueous concentration of 2,4-D. The effect of 2,4-D on ion transport was explained by the hypothesis that a layer of 2,4-D molecules is absorbed within the membrane/water interfacial region, and that the 2,4-D molecules are oriented in such a way that their dipole moment is directed toward the aqueous medium. The results suggest that this layer is located in the hydrocarbon side of the interface. The hypothesis has been confirmed by the measurements of changes of electric potential difference across air/water and air/lipid monolayer/water interfaces. It has been found that the electric potential of the nonpolar side of the interface decreases in the presence of neutral molecules of 2,4-D, which is in agreement with the conclusions drawn from the results of membrane experiments. The effect of the other auxin-type phenoxy herbicides, 2,4,5-T and 2,4-DB on lipid bilayer membranes has been found to be similar to that of 2,4-D. In contrast, the phenoxy acid 2,4,6-T, has very little or no herbicidal activity, and at the same time has small effect on ion transport in membranes. Biologically active 2,4-D derivatives, amino acid conjugates of 2,4-D (isoleucine, leucine and valine conjugates) have been found to be also transport active in a manner similar to 2,4-D. Similar conclusions have been drawn from experiments with natural auxin indole acetic acid. The results obtained in this work suggest the existence of correlation between the biological activity of herbicides acting as plant growth regulators and their ability to enhance transport of positively charged ions across lipid membranes. This work provides insight into the physical origin of such activity.
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Water treatment by reverse osmosis.Trivedi, Chandra Shekhar. January 1971 (has links)
No description available.
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Zirconia based /Nafion coposite membranes for fuel cell applicationsSigwadi, Rudzani 06 1900 (has links)
The nanoparticles of zirconium oxide, sulfated and phosphated zirconia were used to modify a Nafion membrane in order to improve its water retention, thermal stability, proton conductivity and methanol permeability so that it can be used at higher temperatures in fuel cell. These modified Nafion nanocomposite membrane with inorganic nanoparticles have been designed to run at operating temperatures between 120 oC and 140 oC because higher temperature operation reduces the impact of carbon monoxide poisoning, allows attainment of high power density and reduces cathode flooding as water is produced as vapor. The inorganic nanoparticles were incorporated within the Nafion matrix by recast, ion exchange and impregnation methods. The membrane properties were determined by ion exchange capacity (IEC), water uptake,
methanol permeability and proton conductivity. The characterization of the inorganic nanoparticles within the nanocomposite membranes was determined by X-Ray diffraction (XRD), Brunau-Emmett-Teller (BET) surface area and Fourier transform infrared spectroscopy (FTIR) for structural properties. Thermal gravimetric analysis (TGA) and Differential scanning calorimetry (DSC) were used to determine the thermal properties, and the morphological properties were probed by Transmission electron microscopy (TEM) and Scanning electron microscopy (SEM).
Pristine ZrO2, sulfated and phosphated ZrO2 nanoparticles were synthesized successfully. The particle sizes ranged from 30 nm to 10 nm respectively. The resulted particles were incorporated to a Nafion membrane with good dispersity. The conductivity of the nanocomposite membrane were around 0.1037 S/cm at 25 oC with
a higher water uptake of 42 %. These results were confirmed by the highest IEC value of 1.42 meg.g-1 of Nafion/ S-ZrO2 nanocomposites membrane. These high IEC value may due to the incorporation of superacid S-ZrO2 nanoparticles which increased the membrane acid property for providing new strong acid site. / Chemical Engineering / M. Tech. (Chemical Engineering)
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Ion conduction characteristics in small diameter carbon nanotubes and their similarities to biological nanochannelsAmiri, Hasti January 2014 (has links)
In this study, we designed a series of experiments to determine the factors governing ion permeation through individual carbon nanotubes (CNTs) less than 1.5 nm in diameter and 20 µm in length. We then rationalize the experimental results by using a model, which is drawn from previous literature on protein ion channels and is centered around a simplified version of the Gouy-Chapman theory of electrical double layer. Lastly, we experimentally demonstrate and discuss the general similarities in ion permeation characteristics between CNTs and biological ion-selective pores. The role of many potential factors influencing the ion transport is assessed by taking two experimental approaches: (1) studying the effect of electrolyte concentration and composition on channel conductance and reversal potential, and (2) examining a second type of nanochannel as a parallel ion conduction pathway within the same device architecture and measurement set-up, which we refer to as leakage devices. This helps to differentiate the effect of CNT on ionic transport from any other possible source. Taken together, these two experimental methods provide strong evidence that the electrostatic potential arising from ionized carboxyl groups at the nanopore entrance has a significant effect on ionic permeation in a manner consistent with a simple electrostatic mechanism.
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