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71	Development of Nanocomposite Polymer Electrolyte Membranes for Higher Temperature PEM Fuel Cells Jalani, Nikhil H. 27 March 2006 (has links) Proton exchange membrane (PEM) fuel cells are one of the most promising clean energy technologies under development. The major advantages include electrical efficiencies of up to 55 %, high energy densities (relative to batteries), and low emissions. However, the main obstacles to commercialization of PEM fuel cells are related to the limitations of the proton conducting solid polymer electrolytes such as Nafion. These membranes are expensive, mechanically unfavorable at higher temperatures, and conduct protons only in the presence of water, which limits the fuel cell operating temperature to about 80 C. This in turn, results in low fuel cell performance due to slow electrode kinetics and virtually no CO tolerance. The potential operation of PEM fuel cells at higher temperature (above 100 C) can provide many advantages such as improved kinetics at the surface of electrode, which is especially important in methanol and CO-containing reformate feeds, and efficient heat rejection and water management. Another issue above 100 C is the reduction of electrochemical surface area of the electrodes due to shrinkage of electrolyte (Nafion phase) within the catalyst layers. This research work is thus focused on the development of nanocomposite proton exchange membranes (NCPEMs) which are chemically and mechanically more stable at higher temperatures and electrodes which can result into better fuel cell performance. These are composite materials with inorganic acidic nanoparticles incorporated within a host polymer electrolyte membrane such as Nafion. The target operating fuel cell temperature in this work is above 100 oC with relative humidity around 30 to 40 %. To achieve these targets, both theoretical and experimental investigations were undertaken to systematically develop these NCPEMs. Various experimental techniques, namely, TEOM (Tapered Element Oscillating Microbalance), Impedance Spectroscopy, MEA (membrane electrode assembly) testing, Ion Exchange Capacity, Scanning Electron Microscope (SEM), Optical Electronic Holography (OEH), Thermal Gravimetric Analysis (TGA), and Dynamic Mechanical Analysis (DMA) were employed to characterize the NCPEMs. A thermodynamic model was developed to describe sorption in proton-exchange membranes (PEMs), which can predict the complete sorption isotherm. A comprehensive proton transport model was also developed to describe proton diffusion in Nafion/(ZrO2/SO42-) nanocomposite membranes. The conductivity of the in situ sol-gel prepared Nafion/ (ZrO2/SO42-) nanocomposite membranes was accurately predicted by the model as a function of relative humidity (RH) without any fitted parameters. This transport model developed offers a theoretical framework for understanding the proton transfer in nanocomposite membranes and is an insightful guide in systematically developing high proton-conducting nanocomposite. Nafion-MO2(M = Zr, Si, Ti) nanocomposite membranes were synthesized with the goal to increase the proton conductivity and water retention by the membrane at higher temperatures and lower relative humidity (120 C, 40% RH) and also to improve the thermo-mechanical properties. The results obtained are promising and indicate that this is a potentially useful approach for developing PEMs with desirable properties. Finally, commercially available high temperature PBI (polybenzimidazole)-H3PO4 (phosphoric acid) gel membrane fuel cell was investigated in the temperature range of 160-180 C. This system exhibited very good and stable performance in this temperature range. Fuel Cells Polymer Composite High Temperature Nafion Fuel cells Nanostructured materials Polyelectrolytes
72	Design and Development of Higher Temperature Membranes for PEM Fuel Cells Thampan, Tony Mathew 27 May 2003 (has links) Proton-Exchange Membrane (PEM) fuel cells are extremely attractive for replacing internal combustion engines in the next generation of automobiles. However, two major technical challenges remain to be resolved before PEM fuel cells become commercially successful. The first issue is that CO, produced in trace amounts in fuel reformer, severely limits the performance of the conventional platinum-based PEM fuel cell. A possible solution to the CO poisoning is higher temperature operation, as the CO adsorption and oxidation overpotential decrease considerably with increasing temperature. However, the process temperature is limited in atmospheric fuel cells because water is critical for high conductivity in the standard PEM. An increase in operating pressure allows higher temperature operation, although at the expense of parasitic power for the compressor. Further the conventional PEM, Nafion? is limited to 120°C due to it's low glass transition temperature. Thus, the design of higher temperature PEMs with stable performance under low relative humidity (RH) conditions is considered based on a proton transport model for the PEM and a fuel cell model that have been developed. These predictive models capture the significant aspects of the experimental results with a minimum number of fitted parameters and provides insight into the design of higher temperature PEMs operating at low RH. The design of an efficacious high temperature, low RH, PEM was based on enhancing the acidity and water sorption properties of a conventional PEM by impregnating it with a solid superacid. A systematic investigation of the composite Nafion?inorganic PEMs comprising experiments involving water uptake, ion-exchange capacity (IEC), conductivity and fuel cell polarization is presented in the work. The most promising composite is the nano-structured ZrO2/Nafion?PEM which exhibits an increase in the IEC, a 40% increase in water sorbed and a resulting 24% conductivity enhancement vs. unmodified Nafion?112 at 120°C and at RH < 40%. proton exchange membranes fuel cells Zirconia modeling composite membranes conductivity od PEMs Nafion water sorption of PEMs
73	Synthesis of a 4-(Trifluoromethyl)-2-Diazonium Perfluoroalkyl Benzenesuflonylimide (PFSI) Zwitterionic Monomer for Proton Exchange Membrane Fuel Cell Nworie, Chimaroke 01 May 2014 (has links) In order to achieve a more stable and highly proton conducting membrane that is also cost effective, the perfluoroalkyl benzenesulfonylimides (PFSI) polymers are proposed as electrolyte for Proton Exchange Membrane Fuel Cells. 4-(trifluoromethyl)-2-diazonium perfluoro-3, 6-dioxa-4-methyl-7-octene benzenesulfonyl imide (I) is synthesized from Nafion monomer via a 5-step schematic reaction at optimal reaction conditions. This diazonium PFSI zwitterionic monomer can be further subjected to polymerization. The loss of the diazonium N2+ functional group in the monomer is believed to form the covalent bond between the PFSI polymer electrolyte and carbon electrodes support. All the intermediates and final products were characterized using 1H NMR, 19F NMR and IR spectrometry. Organic Chemistry
74	Vieillissement hygrothermique du Nafion Collette, Floraine 27 November 2008 (has links) (PDF) Dans le développement des piles à combustible de type PEMFC (Proton Exchange Membrane Fuel Cells), la durabilité des membranes est une question cruciale. Le vieillissement in-situ du Nafion® dans les piles ne permet pas de dégager de mécanisme de dégradation. C'est pourquoi des tests de vieillissement ex-situ, en enceinte climatique et en étuve, sur une durée de 500 jours ont été réalisés sur du Nafion® 112 et du Nafion® 212-CS dans des conditions proches de celles de la pile en fonctionnement (à 80°C à une hygrométrie variant de 0%RH à 95%RH).<br />L'évolution des propriétés mécaniques montre une augmentation du module d'Young et une diminution de l'allongement à la rupture tandis que l'hydrophilie (directement liée à la conductivité) mesurée par DVS (Dynamic Vapour Sorption) diminue. L'évolution de la structure chimique, suivie par spectroscopie infrarouge, met en évidence la formation d'anhydride sulfonique. Une preuve indirecte de la formation de cette espèce est apportée par la résonnance magnétique nucléaire.<br />Le mécanisme de dégradation proposé est celui de la condensation des acides sulfoniques pour former l'anhydride. L'évolution des propriétés s'explique à la lumière de ce mécanisme.<br />La comparaison du Nafion® 112 et du Nafion® 212-CS montre que le Nafion® 212-CS vieillit trois fois moins vite que le Nafion® 112. La catalyse de la réaction de condensation par les cations métalliques présents en plus grande quantité dans le Nafion® 212-CS est à l'origine de cette différence de cinétique de vieillissement observée.<br />D'autre part, les essais à différentes humidités montrent que lorsque le taux d'hygrométrie croît, la réaction de condensation est accélérée. On propose un mécanisme de dégradation ionique de type SN1 avec formation d'une espèce intermédiaire RSO2+.<br />Enfin, on montre qu'en présence de catalyseur, la réaction de condensation est réversible : il y a hydrolyse de l'anhydride conduisant à des propriétés recouvrées. Il y a rajeunissement de la membrane. Nafion® vieillissement température hygrométrie dégradation sorption conductivité spectroscopie infrarouge RMN
75	Modélisation de la dégradation chimique de membranes dans les piles à combustibles à membrane électrolyte polymère Coulon, Romain 31 January 2012 (has links) (PDF) Cette thèse propose une approche de modélisation de la dégradation chimique par attaque radicalaire de la membrane dans les piles à combustibles à membrane électrolyte polymère, ainsi que à son impact sur la dégradation de la performance électrochimique. La membrane considérée dans cette étude est de type perfluorosulfonique, avec une structure dépen-dant fortement de son humidification et conditionnant les propriétés de transport. Afin d'étudier la dégradation de la membrane, il faut dans un premier temps établir un modèle de transport, qui sera utilisé aussi bien dans le modèle de dégradation que par les modèles de performance de cellule déjà existants. Une fois ce modèle établi, nous nous focalisons sur la partie dégradation chimique. Après une compréhension globale des phénomènes physico-chimiques se déroulant lors de la dégradation, une mise en équation détaillée est nécessaire. Même les concepts utilisés sont relativement simples, le besoin de nombreux paramètres nous a contraint à simplifier le modèle sur certains points, notamment le mécanisme de dégradation chimique, tant la complexité du phénomène est un frein à la paramétrisa-tion du modèle. Ce modèle, avec ses simplifications et ses hypothèses, est ensuite validé, aussi bien d'un point de vue performance que d'un point de vue dégradation. Il est pour finir exploité dans différents cas de figures, allant de l'utilisation ininterrompue à courant constant (test purement utilisé en laboratoire) à un cyclage plus représentatif de conditions de fonctionnement réelles. Piles à combustible Modélisation Dégradation Membrane Nafion PEMFC
76	Molecular Interactions Studied by Electrophoretic and Diffusion NMR Hallberg, Fredrik January 2010 (has links) Even though electrophoretic NMR (eNMR) experiments may provide unique chemical information and have been performed for three decades, the technique is still rarely applied, mainly because several experimental sources of artifacts have to be controlled to achieve accurate results. In this thesis, new experimental setups and protocols for accurate and precise eNMR experiments are presented. These include a novel eNMR sample cell, a radiofrequency filter and methods to suppress bulk flow effects. These developments improved the signal-to-noise ratio by roughly an order of magnitude compared to the U-tube setup previously used for eNMR. Convection-compensated pulse sequences in combination with a phase correction method were found to efficiently suppress bulk flow effects in the experiments and greatly increase experimental accuracy. These experimental setups and protocols were applied to probe association of ions and molecules in solution. It is particularly illustrated that the combination of diffusion and eNMR has great potential to provide quantitative results on ionic and molecular association in a variety of systems. The extent to which ionic surfactants associate with uncharged cyclodextrin probed by eNMR yielded very similar results to those obtained by diffusion NMR experiments. Complexation of a large set of small mono- and polyvalent metal cations to poly(ethylene oxide) was quantified by estimating the effective charge of the polymer through combined diffusion and eNMR information. Significant association was found for cations that have a surface charge density below a critical value. Ion pairing between tetramethylammonium cations and a series of anions in several solvents was also probed by diffusion NMR and eNMR experiments. For the monovalent anions in ethanol and ethanol-water mixture a dependence on ionic size was demonstrated. In water, dimethylsulfoxide, and methanol no such trend and very little pairing was observed. In acetonitrile, a different pattern was seen that did not correlate well with any single ionic parameter. An experimental cell and procedures for electrokinetic studies of solvated proton-conducting polymer materials is also presented. Electro-osmotic flow and diffusion were studied for each molecular component in water-methanol mixtures that swell Nafion membranes. / Elektroforetisk NMR (eNMR) är en experimentell metod som funnits i tre decennier och som kan ge unik kemisk information. Ändå används den sällan då flera experimentella artefakter måste korrigeras för, om man ska få korrekta resultat. I denna avhandling presenteras nya experimentella uppställningar och protokoll ämnade att uppnå korrekta och noggranna resultat. Dessa inkluderar en ny mätcell, ett radiofrekvensfilter och metoder för att minimera effekten av samtidiga bulkflöden i provlösningen. Sammantaget uppnås ungefär en storleksordning högre signal-brus-förhållande jämfört med den U-rörsuppställning som tidigare använts. Konvektions-kompenserande pulssekvenser i kombination med en faskorrektionsteknik minskade också bulkflödeseffekter effektivt, vilket ökade resultatens noggrannhet högst avsevärt. De experimentella uppställningarna och protokollen användes här för att mäta association av joner och molekyler i lösning. Mätningarna visar att kombinationen diffusions- och eNMR har en stor potential att kvantitativt kunna bestämma associationgraden i många olika typer av kemiska system. Associationsgraden mellan joniska tensider och cyklodextriner undersöktes både med eNMR och diffusions-NMR, och resultaten var mycket lika. Komplex-bildningen mellan en serie enkel- och flerladdade metalljoner och poly-(etylenoxid) kvantifierades genom att uppskatta polymerens effektiva laddning från kombinerad diffusions- och eNMR. Betydande komplexbildning hittades för katjoner med ytladdningstäthet under ett kritiskt värde. Jonparbildning mellan tetrametylammoniumjoner och en serie av anjoner i flera olika lösningsmedel undersöktes också med diffusions- och eNMR. För de monovalenta anjonerna i etanol och etanol-vatten-blandning påvisades ett samband med jonstorleken. I vatten, dimetylsulfoxid och metanol var däremot jonparbildningen låg och inget liknande samband hittades. I acetonitril observerades ett annat mönster, som inte korrelerade bra med någon av anjonernas normala joniska karakteristika. Slutligen presenteras en mätcell och procedurer för elektrokinetiska studier i de solvatiserade protonledande polymermaterial som bland annat används i bränsleceller. Elektroosmotiskt flöde och diffusion uppmättes för varje molekylär komponent i Nafion-membran solvatiserade av vatten-metanol-blandningar. / QC20100709 Physical chemistry NMR electrophoretic NMR Ion pairing complexation association diffusion pulsed field gradient Nafion Spectroscopy Spektroskopi
77	An intracellular glucose biosensor based on nanoflake ZnO Fulati, Alimujiang, Usman Ali, Syed M., Asif, Muhammad H., Hassan Alvi, Naveed Ul, Willander, Magnus, Brännmark, Cecilia, Strålfors, Peter, Börjesson, Sara I., Elinder, Fredrik, Danielsson, Bengt January 2010 (has links) In this study, an improved potentiometric intracellular glucose biosensor was fabricated with immobilization of glucose oxidase on a ZnO nanoporous material. The ZnO nanoporous material with a wall thickness around 200 nm was grown on the tip of a borosilicate glass capillary and used as a selective intracellular glucose sensor for the measurement of glucose concentrations in human adipocytes and frog oocytes. The results showed a fast response within 4 s and a linear glucosedependent electrochemical response over a wide range of glucose concentration (500 nM-10 mM). The measurements of intracellular glucose concentrations with our biosensor were consistent with the values of intracellular glucose concentrations reported in the literature. The sensor also demonstrated its capability by detecting an increase in the intracellular glucose concentration induced by insulin. We found that the ZnO nanoporous material provides sensitivity as high as 1.8 times higher than that obtained using ZnO nanorods under the same conditions. Moreover, the fabrication method in our experiment is simple and the excellent performance of the developed nanosensor in sensitivity, stability, selectivity, reproducibility and anti-interference was achieved. All these advantageous features of this intracellular glucose biosensor based on functionalised ZnO nanoporous material compared to ZnO nanorods demonstrate a promising way of enhancing glucose biosensor performance to measure reliable intracellular glucose concentrations within single living cells. / <p>Original Publication:Alimujiang Fulati, Syed M. Usman Ali, Muhammad H. Asif, Naveed Ul Hassan Alvi, Magnus Willander, Cecilia Brännmark, Peter Strålfors, Sara I. Börjesson and Fredrik Elinder, An intracellular glucose biosensor based on nanoflake ZnO, 2010, Sensors and actuators. B, Chemical, (150), 2, 673-680.http://dx.doi.org/10.1016/j.snb.2010.08.021Copyright: Elsevier Science B.V., Amsterdam.http://www.elsevier.com/</p> Glucose oxidase (GOD) Intracellular Potentiometric biosensor Nanoflake ZnO Nafion membrane NATURAL SCIENCES NATURVETENSKAP
78	Nanocomposite Nafion And Heteropolyacid Incorporated Mesoporous Catalysts For Dimethyl Ether Synthesis From Methanol Ciftci, Aysegul 01 August 2009 (has links) (PDF) The need for alternative transportation fuels is rising with the rapid depletion of oil reserves and the simultaneous growth of the world&amp / #8217 / s population. Production of dimethyl ether, a non-petroleum derived attractive fuel-alternate for the future, is a challenging research area. Different routes and various solid-acid catalysts are being developed in order to achieve the most efficient way of synthesizing this potential diesel alternative fuel. The focus of heterogeneous catalysis is to convert renewable feed stocks to valuable chemicals. Nafion resin and heteropolyacid compounds are active acidic catalysts with significantly low surface areas, which act as a strong barrier limiting their catalytic activity. Synthesizing solid-acid catalysts by incorporation of nonporous active compounds into mesoporous silicate structured materials opens a door to producing valuable chemicals by heterogeneous catalysis. The objective of this work was to synthesize and characterize nafion and heteropolyacid incorporated nanocomposite catalysts and to catalyze DME synthesis by dehydration of methanol at different temperatures. The interactions of methanol and DME with these catalysts were also investigated by in situ FT-IR. Silicotungstic acid (STA)/Silica and Tungstophosphoric acid (TPA)/Silica catalysts were synthesized by following a one-pot hydrothermal route. These mesoporous catalysts had surface area values of 143-252 m2/g. The STA/SiO2 nanocomposite catalyst having a W/Si atomic ratio of 0.33 showed the highest activity, with a DME selectivity approaching to 100% and a methanol conversion of 60% at 250&deg / C at a space time of 0.27 s.g.cm-3. Effects of W/Si atomic ratio and the synthesis procedure on the performance of these novel materials were investigated. Nanocomposite Nafion/SiO2 solid-acid catalysts having high surface area values (595-792 m2/g) and narrow pore size distributions (4.3 nm) were successfully synthesized by a one-pot hydrothermal procedure. Effects of the modifications in the synthesis procedure concerning the surfactant removal, nafion loading, etc. were investigated based on the characterization results and activity tests. Nafion was observed to be uniformly distributed within these mesoporous catalysts. Nafion resin was also impregnated into aluminosilicate and &amp / #945 / -alumina, but one-pot synthesis was concluded to be better for obtaining well dispersed, nafion incorporated active catalysts. The Nafion/Silica catalyst synthesized by a nafion/silica weight ratio of 0.15 and washed with 2M sulfuric acid-ethanol solution exhibited the highest activity due to its highest Br&ouml / nsted, as well as Lewis acidity. A methanol conversion of 40% at 300&deg / C, 0.27 s.g.cm-3 and DME selectivity values approaching to 100% over 180&deg / C were very promising for the synthesis of this green fuel alternate over the new catalysts synthesized. QD Chemistry 1-999
79	Development of new membranes for proton exchange membrane and direct methanol fuel cells Yang, Bo, Ph. D. 14 May 2015 (has links) Proton exchange membrane fuel cells (PEMFC) and direct methanol fuel cells (DMFC) are drawing much attention as alternative power sources for transportation, stationary, and portable applications. Nafion membranes are presently used in both PEMFC and DMFC as electrolytes, but are confronted with a few difficulties: (i) high cost, (ii) limited operating temperature of < 100 °C, and (iii) high methanol permeability. With an aim to overcome some of the problems encountered with the Nafion membranes, this dissertation focuses on the design and development of a few materials systems for use in PEMFC and/or DMFC. The incorporation of hydrous Ta₂O₅·nH₂O into Nafion membrane as well as the electrodes is shown to help the cell to retain water to higher temperatures. Membrane-electrode assembly (MEA) consisting of the composite membrane shows better cell performance at 100 and 110 °C than that with plain Nafion membrane, and a high power density of ~ 650 mW/cm² at 100 °C is obtained with H₂ - CO mixture as the fuel due to a significant alleviation of the CO poisoning of the catalysts. Sulfonated poly(etheretherketone) (SPEEK) membranes with various sulfonation levels are prepared and investigated in DMFC. With a sulfonation level of ~ 50 %, the SPEEK membranes exhibit low methanol permeability and electrochemical performance comparable to that of Nafion at around 60 °C, making it an attractive low-cost alternative to Nafion. From a comparative study of the structural evolutions with temperature in 2 M methanol solution, it is found that the lower methanol permeability of SPEEK membranes is related to the less connected and narrower pathways for water/methanol permeation. The dry proton conductor CsHSO₄ shows a high proton conductivity of ~ 10⁻³ S/cm at temperatures > 140 °C and water is not needed for proton conduction. However, it is found that CsHSO₄ decomposes to Cs₂SO₄ and H₂S at 150 °C in H₂ atmosphere in contact with the Pt/C catalyst. Thus, new catalyst materials need to be explored for CsHSO₄ to be used in practical high temperature PEMFC. Thin self-humidifying Nafion membranes with dispersed Pt/C catalyst powder are prepared and tested in PEMFC with dry H₂ and O₂. The Pt/C particles provide sites for catalytic recombination of H₂ and O₂ permeating from the anode and cathode, and the water produced at these sites directly humidifies the membrane. The performance of the cell with the self-humidifying membrane operated with dry reactants is ~ 90 % of that obtained with well humidified H₂ and O₂. / text Proton exchange membrane fuel cells Direct methanol fuel cells Proton exchange Membranes Nafion membranes
80	Thermodynamics of sorption and distribution of water in nafion Elfring, Gwynn Johan 06 April 2010 (has links) In this work a model for the wetting and swelling of pores with water within a Nafion membrane is developed. This model is based on minimizing all contributions to the total free energy of the proposed system. We find that equilibrium state depends on entropic mixing forces and energetic surface forces. The wetting of the pore relies on the entropic forces exceeding the energetic forces. Specifically this indicates a critical pore size in which liquid is the favorable state. If the pore fills with liquid it will swell until balanced by the energy of the deforming membrane. Several factors including pressure relative to saturation and the phase which hounds the membrane are shown to dramatically affect the final equilibrium state of the system. Nafion membrane Pores

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