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51	Polymer/nano-organic composite proton exchange membranes for direct methanol fuel cell application. Luo, Hongze January 2005 (has links) The proton exchange membrane is one key component of direct methanol fuel cells, which has double functions of conducting protons, separating fuels and oxidant. At present, the performance and price of sulfonic acid proton exchange membrane used in direct methanol fuel cells are deeply concerned. In order to reduce membrane 's cost and improve performance of Nafion membrane, three different kinds of membranes have been studied in this thesis. These membranes are SPEEK membranes, SPEEK/ZP composite membranes and Nafion/ZP composite membranes. Fuel cells Membranes (Technology)
52	The development of inorganic and organic/inorganic membranes for DMFC application. Mokrani, Touhami January 2004 (has links) A fuel cell is an energy device that converts chemical energy to electrical energy. Low temperature fuel cells, namely the hydrogen fuel cell and the direct methanol fuel cell are preferred amongst other fuel cell types for stationary and vehicular applications, due to their small size and their low operating temperature. The direct methanol fuel cell has several advantages over the hydrogen fuel cell including ease of transport and storage since methanol is a liquid. Since methanol is used directly in the cell there is no need for a reforming process, which results in a less complicated system. However, direct methanol fuel cell are in their infancy and many problems need to be overcome before reaching commercialization. The direct methanol fuel cell has several disadvantages, namely, the sluggish methanol oxidation reaction, the high cost of state-of-the-art proton exchange membranes, the high methanol permeability from anode to cathode and the dependence on the conductivity on membrane water content, which limits their use to temperatures below the boiling point of water, while the need is to work at high temperatures. Attempts to overcome the disadvantages of the state-of-the-art membrane were made in this study, including the development on novel proton exchange membranes and also the modification of existing state-of-the-art membranes. Fuel cells Membranes (Technology)
53	Preparation and characterization of highly active nano pt/c electrocatalyst for proton exchange membrane fuel cell. Ying, Qiling January 2006 (has links) <p>Catalysts play an essential role in nearly every chemical production process. Platinum supported on high surface area carbon substrates (Pt/C) is one of the promising candidates as an electrocatalyst in low temperature polymer electrolyte fuel cells. Developing the activity of the Pt/C catalyst with narrow Pt particle size distribution and good dispersion has been a main concern in current research.</p> <p><br /> In this study, the main objective was the development and characterization of inexpensive and effective nanophase Pt/C electrocatalysts. A set of modified Pt/C electrocatalysts with high electrochemical activity and low loading of noble metal was prepared by the impregnation-reduction method in this research. The four home-made catalysts synthesized by different treatments conditions were characterized by several techniques such as EDS, TEM, XRD, AAS, TGA, BET and CV.</p> <p><br /> Pt electrocatalysts supported on acid treatment Vulcan XC-72 electrocatalysts were produced successfully. The results showed that Pt particle sizes of Pt/C (PrOH)x catalysts between 2.45 and 2.81nm were obtained with homogeneous dispersion, which were more uniform than the commercial Pt/C (JM) catalyst. In the electrochemical activity tests, ORR was confirmed as a structure-sensitive reaction. The Pt/C (PrOH/pH2.5) showed promising results during chemically-active surface area investigation, which compared well with that of the commercial standard Johnson Matthey Pt/C catalyst. The active surface area of Pt/C (PrOH/pH2.5) at 17.98m2/g, was higher than that of the commercial catalyst (17.22 m2/g ) under the conditions applied. In a CV electrochemical activity test of Pt/C catalysts using a Fe2+/Fe3+ mediator system study, Pt/C (PrOH/pH2.5) (67mA/cm2) also showed promise as a catalyst as the current density is comparable to that of the commercial Pt/C (JM) (62mA/cm2).</p> <p><br /> A remarkable achievement was attained in this study: the electrocatalyst Pt supported on CNTs was synthesized effectively. This method resulted in the smallest Pt particle size 2.15nm. In the electrochemically-active surface area study, the Pt/CNT exhibited a significantly greater active surface area (27.03 m2/g) and higher current density (100 mA/cm2) in the Fe2+/Fe3+ electrochemical mediator system than the other home-made Pt/C catalysts, as well as being significantly higher than the commercial Pt/C (JM) catalysts. Pt/CNT catalyst produced the best electrochemical activities in both H2SO4 and K4[Fe(CN)6] electrolytes. As a result of the characteristics of Pt/CNT, it can be deduced that the Pt/CNT is the best electrocatalyst prepared in this study and has great potential for use in fuel cell applications.</p> Electrocatalysis Fuel cells.
54	Synthesis and characterisation of proton conducting membranes for direct methanol fuel cell (DMFC) applications. Mohamed, Rushanah January 2005 (has links) <p>For a direct methanol fuel cell (DMFC), the proton exchange membrane must conduct protons and be a good methanol barrier. In addition to the high methanol permeability achieved by these membranes, they are very expensive and contribute greatly to theoverall cost of fuel cell set up. The high cost of the DMFC components is one of the main issues preventing its commercialization. The main objective of this study was thus to produce highly proton conductive membranes that are cheap to manufacture and have low methanol permeability.</p> Fuel cells Membranes (Technology)
55	Chemical sensors and instrumentation powered by microbial fuel cells Angathevar Veluchamy, Raaja Raajan. January 2007 (has links) (PDF) Thesis (M.S.)--Montana State University--Bozeman, 2007. / Typescript. Chairperson, Graduate Committee: Joseph D. Seymour. Includes bibliographical references (leaves 44-47). Fuel cells. Detectors.
56	Mixed reactant single chamber fuel cell, using products generated from the electrolysis of an aqueous electrolyte / Jost, William C. January 1900 (has links) Thesis (M.S.)--Oregon State University, 2008. / Printout. Includes bibliographical references (leaves 87-90). Also available on the World Wide Web. Fuel cells Electrolysis.
57	Modeling a fuel cell system fo residential dwellings Trueblood, Christopher P. Halpin, S. Mark, January 2006 (has links) (PDF) Thesis(M.S.)--Auburn University, 2006. / Abstract. Vita. Includes bibliographic references. Dwellings Fuel cells.
58	Fuel cell cathode air filters methodologies for design and optimization / Kennedy, Daniel Mabry. Tatarchuk, Bruce J. January 2007 (has links) (PDF) Thesis(M.S.)--Auburn University, 2007. / Abstract. Includes bibliographic references (p.75-77). Fuel cells Air filters
59	Electrochemical impedance spectroscopy of proton exchange membrane fuel cell stacks Hetzer, Brian J. January 1900 (has links) Thesis (M.S.)--West Virginia University, 2004. / Title from document title page. Document formatted into pages; contains xi, 100 p. : ill. (some col.). Includes abstract. Includes bibliographical references (p. 87-88). Impedance spectroscopy. Fuel cells.
60	Silver-perovskite composite materials for SOFC cathode-interconnect contact a thesis presented to the faculty of the Graduate School, Tennessee Technological University / Wilkinson, Lucas T., January 2009 (has links) Thesis (M.S.)--Tennessee Technological University, 2009. / Title from title page screen (viewed on Aug. 25, 2009). Bibliography: leaves 68-71. Solid oxide fuel cells

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