Browsing by Author "Naidoo, Sivapregasen"

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    Cesium hydrogen sulphate and cesium dihydrogen phosphate based solid composite electrolyte for fuel cell application
    (University of the Western Cape, 2004) Naidoo, Sivapregasen; Linkov, Vladimir; Vaivars, Guntars; Dept. of Chemistry; Faculty of Science
    A new high temperature solid electrolyte composite was developed, with CsHSO4 and CsH2PO4 as the proton conducting material in composition with PTFE and SiO2 to enhance the solid electrolyte composites mechanical strength and conductivity. Conductivity measurements for CsHSO4 and CsH2PO4 and composites thereof, in temperature ranges 0 to 180 oC and 0 to 250 oC respectively, were carried out. The composites with different concentrations PTFE and silica were tested for stability in a enhanced conductivity. hydrogen atmosphere and different degrees of humidity. The CsHSO4 was seen to exhibit a super protonic phase change at temperatures between 132 – 140 C and CsH2PO4 around 230 C. The presence of the PTFE proved to be a stabilizing factor in the reduction of water re-adsorption once the membrane had been dried during thermal conductivity analysis. According to supporting data in the literature it has been found that composites including silica could be influenced by the hydrophilicity and specific surface area of the silica. In the composite system employed it was shown by impedance analysis the presence of two semi-circles in the Nyquist representation for the enhanced conductivity due the presence of silica.
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    Synthesis of multi-metallic catalysts for fuel cell applications
    (University of the Western Cape, 2008) Naidoo, Sivapregasen; Vaivars, Guntars; Dept. of Chemistry; Faculty of Science
    The direct methanol fuel cell or DMFC is emerging as a promising alternative energy source for many applications. Developed and developing countries, through research, are fast seeking a cheap and stable supply of energy for an ever-increasing number of energy-consuming portable devices. The research focus is to have DMFCs meeet this need at an affordable cost is problematic. There are means and ways of making this a reality as the DMFC is found to be complementary to secondary batteries when used as a trickle charger, full charger, or in some other hybrid fuel cell combination. The core functioning component is a catalyst containing MEA, where when pure platinum is used, carbon monoxide is the thermodynamic sink and poisons by preventing further reactions at catalytic sites decreasing the life span of the catalyst if the CO is not removed. Research has shown that the bi-functional mechanism of a platinum-ruthenium catalyst is best because methanol dehydrogenates best on platinumand water dehydrogenation is best facilitated on ruthenium. It is also evident that the addition of other metals to that of PtRu/C can make the catalyst more effective and effective and increase the life span even further. In addition to this, my research has attempted to reduce catalyst cost for DMFCs by developing a low-cost manufacturing technique for catalysts, identify potential non-noblel, less expensive metallic systems to form binary, ternary and quarternary catalysts.