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Elaboration et réactivité interfaciale d'oxydes pérovskites à base de Lanthane Strontium Chrome Ruthénium (LSCrRu) comme composés d'anode de piles à combustible à température intermédiaire (ITSOFC).Combemale, L. 17 November 2005 (has links) (PDF)
Cette étude apporte des données sur l'intérêt des chromites de lanthane strontium dopés au ruthénium La1-xSrxCr1-yRuyO3δ (LSCrRu) comme anode de pile à combustible ITSOFC. La synthèse sous champ micro-onde d'oxydes mixtes a permis la mise en forme de demi-cellules et cellules complètes modèles par pulvérisation cathodique magnétron et par sérigraphie. Les propriétés de reformage de CH4 ont pu être étudiées dans un dispositif mono-chambre couplé à un spectromètre de masse en collaboration avec l'Institut de REcherche Hydro-Québec. La réactivité à l'interface anode/électrolyte a été analysée par SIMS et XRD sur demi-cellules modèles vieillies sous H2 à 800°C. Elle a permis de préciser la chimie du film après traitement. Les cellules complètes, testées en condition de fonctionnement, ont mis en évidence, après dissolution sélective de LSCrRu, une modification de la microstructure à l'interface anode/électrolyte. Des analyses XPS et SEM-EDX n'ont pas montré de réactivité chimique.
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Pt Nanophase supported catalysts and electrode systems for water electrolysis.Petrik, Leslie Felicia. January 2008 (has links)
<p>In this study novel composite electrodes were developed, in which the catalytic components were deposited in nanoparticulate form. The efficiency of the nanophase catalysts and membrane electrodes were tested in an important electrocatalytic process, namely hydrogen production by water electrolysis, for renewable energy systems. The activity of electrocatalytic nanostructured electrodes for hydrogen production by water electrolysis were compared with that of more conventional electrodes. Development of the methodology of preparing nanophase materials in a rapid, efficient and simple manner was investigated for potential application at industrial scale. Comparisons with industry standards were performed and electrodes with incorporated nanophases were characterized and evaluated for activity and durability.</p>
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New Materials for the Molten Carbonate Fuel CellRandström, Sara January 2008 (has links)
Smältkarbonatbränslecellen (MCFC) är en högtemperaturbränslecell för stationära applikationer. Den har samma höga totalverkningsgrad som konventionella kraftvärme-anläggningar, men kan byggas i mindre moduler (från 250 kWe). De små modulerna och den bränsleflexibilitet (naturgas, biogas, etanol, diesel) som MCFC har, gör den intressant för exempelvis industrier med organiska restprodukter och höga krav på tillförlitlighet. Den höga temperaturen och närvaron av en saltsmälta gör dock materialdegradering till en viktig faktor för forskning och utveckling inom området. För även om de fälttester som nyligen gjorts har visat på att vissa av degraderingsprocesserna är mindre allvarliga än förväntat, finns fortfarande ett behov av utveckling för att sänka kostnaderna och förlänga livstiden. I första delen av detta arbete undersöktes material för olika delar av cellen inom ramarna för EU-projektet IRMATECH. Materialen ansågs vara interessanta alternativ till de nuvarande materialen på grund av deras lägre kostnad och/eller bättre prestanda. Två alternativa anodströmtilledarmaterial undersöktes. För anodströmtilledaren är korrosionen och den elektriska resistansen av det eventuella oxidlagret nyckelparametrar. Dessa parametrar undersöktes och utvärderades. Fastän de båda alternativa materialen hade oxidlager med låg resistans, fanns indikationer på korrosionsprocesser som kan äventyra materialets långtidsstabilitet. För katodmaterialet, NiO, har upplösningen varit problemet. De upplösta nickeljonerna fälls ut i elektrolyten och bildar dendriter som kan kortsluta cellen. Därför undersöktes nickelupplösningen hos tre alternativa katodmaterial. Det mest lovande materialet, en nickeloxid-katod dopad med magnesium och järn testades i en singelcell för att studera elektrokemisk prestanda, morfologi och områden där nickelutfällning skett. Resultaten visade att prestandan var jämförbar med NiO, men att den mekaniska stabiliteten måste undersökas ytterligare. I ”wet-seal”-området är det rostfria stålet belagt med ett aluminiumskikt för att skydda det från den mycket korrosiva miljön. Tillverkningsprocesserna för dessa aluminiumbeläggningar har hittills varit dyra och komplexa. Därför utvärderades en alternativ tillverkningsprocess. Beläggningen, studerad i både reducerande och oxiderande miljö visade en tendens till att spricka och därmed exponera det underliggande rostfria stålet. Detta berodde troligtvis på en manuell beläggningsprocess som resulterade i ett inhomogent ytskikt. I den andra delen av arbetet föreslogs en alternativ tillverkningsmetod, baserad på nyligen publicerade resultat där man elektrodeponerat aluminium från jonvätskor. Dessa har ett större katodiskt fönster än vatten och möjliggör därför elektrodeponering av elektropositiva material. För att göra processen industrivänlig provades ett alternativ till den vanligen använda aluminiumtrikloriden. Det visade sig dock att påverkan av miljön på stabiliteten hos jonvätskan behövde undersökas innan några material kunde tillverkas. Vatten i kombination med syre visade sig ha en stor inverkan på den katodiska strömtätheten. I frånvaro av dessa komponenter var jonvätskan mycket stabil. / The Molten Carbonate Fuel Cell (MCFC) is a high temperature fuel cell for stationary applications. It has the same high over-all efficiency (90%) as traditional combined heat and power plants, but MCFC can be built in small modules (from 250 kWe). The small modules in combination with fuel flexibility (natural gas, biogas, ethanol, diesel) makes MCFC an interesting alternative for industries with organic waste and high demands for reliability. The high temperature (650 °C) and the presence of molten salt result however in material degradation. Corrosion and dissolution of the materials used have been the challenge for MCFC. Although long-term field trials have shown that some of the material problems are not as severe as first believed, further material development is necessary to decrease the cost and prolong the life-time. In the first part of this work, materials for different parts of the cell were tested within the EU project IRMATECH. The materials were interesting alternatives to the state-of-the-art materials due to their lower cost and/or better performance. Two alternative anode current collector materials were tested. For the anode current collector the corrosion and electrical resistance of the possible oxide layer are key parameters. These parameters were investigated and evaluated. Although both the materials showed a low resistance, there were indications of corrosion processes which could affect the life-time of the material. For the cathode material, NiO, the dissolution of the material has been a problem. The dissolved nickel ions precipitate in the electrolyte and form conductive nickel dendrites that eventually short-circuit the cell. Therefore, the nickel dissolution of three alternative cathode materials was tested. The most promising material, a NiO doped with magnesium and iron, was tested in a single cell to study the electrical performance, the morphology after operation and the area where nickel had precipitated. The results showed that the performance was comparable to NiO, but it is necessary to investigate the mechanical strength of the material further. In the wet-seal area, the stainless steel is coated with an aluminium coating to protect the material from a severe corrosion environment. The production of aluminium coatings has so far been expensive and complex and an alternative coating process was evaluated. The alternative coating, tested in both reducing and oxidising environments showed a tendency to crack and expose the stainless steel to the corrosive environment. This was suggested being due to the manual coating process that resulted in inhomogeneous coatings. In the second part, an alternative process to coat the wet-seal was suggested, based on recently published results where aluminium had been electrodeposited from ionic liquids. These solvents have a wider electrochemical window than water, and electropositive materials can therefore be deposited. To make the coating process suitable for industrial applications, an alternative to the commonly used AlCl3 was tested. It was shown however, that the influence of the environment had to be investigated before any materials could be produced. The environment, especially water in combination with oxygen was shown to influence the cathodic current density. In absence of these components, the ionic liquid was shown to be very stable. / QC 20100906
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Electrical properties of BaZr0.1Ce0.7Y0.1Yb0.1O3-δ and its application in intermediate temperature solid oxide fuel cellsRainwater, Benjamin H. 06 July 2012 (has links)
Conventional oxygen anion conducting yttria-stabilized zirconia (YSZ) based solid oxide fuel cells (SOFCs) operate at high temperatures (800oC-1000oC). SOFCs based on proton conducting ceramics, however, can operate at intermediate temperatures (450oC-750oC) due to low activation energy for protonic defect transport when compared to oxygen vacancy transport. Fuel cells that operate at intermediate temperatures ease the critical materials requirements of cell components and reduce system costs, which is necessary for large scale commercialization. BaCeO3-based perovskite materials are candidates for use as ion conductors in intermediate temperature SOFCs (IT-SOFCs) when doped with trivalent cations in the B-site. B-site doping forms oxygen vacancies which greatly increases the electrical conductivity of the material. The oxygen vacancies are consumed during the creation of protonic defects or electronic defects, depending on the atmosphere and temperature range. High performance IT-SOFCs based on the Y3+ and Yb3+ doped BaCeO3-based system, BaZr0.1Ce0.7Y0.1Yb0.1O3-δ (BZCYYb) have been recently reported. High conductivity in O2/H2O atmosphere was reported, however, a more basic understanding of the BZCYYb structure, electrical conductivity, and the portion of the charge carried by each charge carrier under fuel cell conditions is lacking. In this work, the BZCYYb material is fabricated by the solid state reaction method and the crystal structure at intermediate temperatures is studied using HT-XRD. The total conductivity of BZCYYb in H2/H2O, O2/H2O, and air atmospheres in the IT-SOFC temperature range is reported. The activation energy for transport at these conditions is determined from the conductivity data and the transference numbers of protonic defects, oxygen anion defects and electronic defects in the BZCYYb material are determined by the concentration cell - OCV method. BZCYYb is a mixed proton, oxygen anion, and electronic conductor at IT-SOFC temperature ranges (450oC - 750oC), in H2, O2, and H2O containing atmospheres.
Ni-BZCYYb/BZCYYb/BZCYYb-LSCF fuel cells were constructed and peak power densities of ~1.2 W/cm2 were reported at 750oC after optimization of the Ni-BZCYYb anode porosity. Decreasing the Ni-BZCYYb anode porosity did not significantly affect the electrical conductivity of the anode, however the peak power densities of the IT-SOFCs based on the anode with less porosity, calculated from I-V curve data, showed dramatic improvement. The fuel cell with the lowest anode porosity demonstrated the highest performance. This finding is in stark contrast to the optimal anode porosity needed for high performance in YSZ-based, oxygen anion conducting SOFCs. Because of significant proton conduction in the BZCYYb material, fuel cell reaction products (water) form at the cathode side and less porosity is required on the anode side. The improvement in performance in the BZCYYb based IT-SOFC is attributed to the unique microstructure formed in the Ni-BZCYYb anode when no pore forming additives are used which may contribute to high electrocatalytic behavior for anode reactions.
This work provides a basic understanding of the electrical properties of BZCYYb and clarifies the feasibility of using BZCYYb in each component of the IT-SOFC system as well as in other electrochemical devices. The high performance of the Ni-BZCYYb/BZCYYb/BZCYYb-LSCF IT-SOFC, due to low anode porosity, provides a new understanding for the rational development of high performance IT-SOFCs based on electrolytes with significant protonic conduction.
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Development of Advanced Optics and High Resolution Instrumentation for Mass Spectrometry Based ProteomicsSherrod, Stacy D. 14 January 2010 (has links)
Imaging mass spectrometry (MS) analysis allows scientists the ability to obtain
spatial and chemical information of analytes on a wide variety of surfaces. The ability to
image biological analytes is an important tool in many areas of life science research,
including: the ability to map pharmaceutical drugs in targeted tissue, to spatially
determine the expression profile of specific proteins in healthy vs. diseased tissue states,
and to rapidly interrogate biomolecular microarrays. However, there are several avenues
for improving the imaging MS experiment for biological samples. Three significant
directions this work addresses include: (1) reducing chemical noise and increasing
analyte identification by developing sample preparation methodologies, (2) improving
the analytical figures of merit (i.e., spatial resolution, analysis time) by implementing a
spatially dynamic optical system, and (3) increasing both mass spectral resolution and
ion detection sensitivity by modifying a commercial time-of-flight (TOF) MS.
Firstly, sample methodology schemes presented in these studies consist of
obtaining both ?top-down? and ?bottom-up? information. In that, both intact mass and
peptide mass fingerprinting data can be obtained to increase protein identification. This sample methodology was optimized on protein microarrays in preparation for bio tissue
analysis. Other work consists of optimizing novel sample preparation strategies for
hydrated solid-supported lipid bilayer studies. Sample methods incorporating
nanomaterials for laser desorption/ionization illustrate the ability to perform selective
ionization of specific analytes. Specifically, our results suggest that silver nanoparticles
facilitate the selective ionization of olefin containing species (e.g., steroids, vitamins).
Secondly, an advanced optical design incorporating a spatially dynamic optical
scheme allows for laser beam expansion, homogenization, collimation, shaping, and
imaging. This spatially dynamic optical system allows user defined beam shapes,
decreases analysis times associated with mechanical movement of the sample stage, and
is capable of increasing the MS limits of detection by simultaneously irradiating multiple
spots.
Lastly, new data acquisition strategies (multiple anode detection schemes) were
incorporated into a commercial time-of-flight mass spectrometer to increase both
sensitivity and resolution in a matrix assisted laser desorption/ionization mass
spectrometer. The utility of this technique can be applied to many different samples,
where high mass spectral resolution allows for increased mass measurement accuracy.
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Etude cinétique de la dégradation électrochimique de composés organiques sur l'anode de diamant dope au bore : Application à la dépollution d'effluents aqueux.Weiss, Elsa 06 October 2006 (has links) (PDF)
Ce travail a pour objectif l'étude de la minéralisation par oxydation électrochimique de composés organiques contenus dans des effluents aqueux. Les composés modèles étudiés sont le phénol et les acides carboxyliques issus de son oxydation (acides maléique, oxalique et formique). Les performances de l'anode de diamant dopé au bore (DDB) ont été comparées à celles d'une électrode commerciale de PbO2, sous les mêmes conditions hydrodynamiques. La minéralisation du phénol en solution aqueuse montre que l'anode de DDB possède les meilleures propriétés électrocatalytiques et énergétiques. Des études cinétiques, réalisées sur des solutions d'acide maléique en présence d'acides oxalique et/ou formique, ont montré que l'acide oxalique s'oxyde par transfert direct d'électrons avec l'électrode tandis que les acides maléique et formique réagissent avec les radicaux hydroxyles électrogénérés. D'autre part, l'électrolyte support peut jouer un rôle sur le processus d'oxydation : en présence d'ions perchlorates, le transfert d'atomes d'oxygène sur la molécule d'acide maléique est beaucoup plus important que celui prévu par le seul processus faradique. Ce résultat est interprété en admettant la formation de radicaux perchlorates par oxydation à un électron. Le procédé électrochimique a été appliqué au traitement d'émulsions représentatives d'effluents de l'industrie métallurgique. Sous certaines conditions expérimentales, la minéralisation est totale ; la dégradation du tensioactif (dodécylbenzènesulfonate de sodium) et de la phase organique (alcool lauryle, acide laurique ou oléique) s'effectue sans démixtion. La résolution numérique d'un modèle physico-chimique a démontré que l'oxydation des molécules organiques par les radicaux hydroxyles se produit dans une couche réactionnelle dont l'épaisseur est environ 1000 fois plus fine que la zone de diffusion des espèces organiques.
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An investigation into the practical and theoretical aspects of hybrid cathodic protectionHolmes, Steven January 2012 (has links)
Galvanic anode technology has in recent years come to the fore as a cost-effective method of successfully mitigating the corrosion of reinforcing steel in concrete structures. Developments in the field of cathodic protection have included the introduction of a novel Hybrid anode system, which uses the same sacrificial anode to pass a short-term impressed current before being connected to the steel directly to provide a long-term galvanic current. Galvanic and hybrid technologies are often seen as less powerful solutions in the treatment of reinforcement corrosion, and the test methodologies which determine the efficacy of cathodic protection systems favour impressed current technologies. The work completed has investigated the application of traditional and novel corrosion assessment techniques to laboratory samples to assess the protection offered by the hybrid treatment methodology in both treatment phases. In addition, the response of both galvanic and hybrid anodes to environmental conditions has been recorded and assessed before being discussed in the context of steel protection criteria. Finally, an investigation is presented into the on-site deterioration of commercially pure titanium feeder wire installed as part of the hybrid anode system and potential solutions to the problem have been documented. The research undertaken found that the hybrid anode system is capable of protecting steel in challenging, aggressive environments. This was confirmed by steel corrosion rate and indicative steel potential measurements. The responsive behaviour investigation showed that the current output of galvanic and hybrid anodes responds rapidly to changes in the corrosion risk posed to the steel and that this has a direct effect on anode system lifetimes. An assessment of the polarisation-based protection criteria applied to steel in concrete has found that the standard inhibits the use of responsive behaviour, and that revisions which consider the present risk of steel corrosion by considering the corrosion current resulting from the relative aggressivity of the concrete environment would be more valid in their application. A cathodic protection system based on the concepts of pit re-alkalisation and pH maintenance can fully utilise galvanic anode responsive behaviour. It was discovered that the deterioration of commercially pure titanium feeder wire seen on site installations was due to anodising in the presence of chloride media which had the potential to lead to pitting corrosion. The pitting risk varied depending on the duration of the treatment and proximity to the installed anode. An anodically grown oxide delayed the onset of corrosion in aqueous KBr solution, but did not significantly increase the pitting potential.
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Χαρακτηρισμός και έλεγχος ιδιοτήτων των μικτών οξειδίων στο σύστημα ZrO2-Y2O3-TiO2 (Cr2O3) καθώς και των κεραμομεταλλικών Ni/ZrO2-Y2O3-TiO2, ως υλικών ανόδου κελίου καυσίμου στέρεου ηλεκτρολύτη (SOFC) / Physical characterization and properties control of the ZrO2-Y2O3-TiO2 (Cr2O3) mixed oxides as well as the Ni/ZrO2-Y2O3-TiO2, cermets as anode materials of solid oxide fuel cell (SOFC)Σκαρμούτσος, Διονύσιος Σ. 24 June 2007 (has links)
Στα πλαίσια της αναζήτησης νέων µεθόδων παραγωγής ενέργειας υψηλής απόδοσης και φιλικής προς το περιβάλλον, ένα µεγάλο µέρος των ερευνητικών δραστηριοτήτων σε διεθνή κλίµακα έχει στραφεί στην ανάπτυξη της τεχνολογίας των κελίων καυσίµου στερεού ηλεκτρολύτη, SOFC’s (Solid Oxide Fuel Cell’s). Λόγω της φιλικότητάς τους προς το περιβάλλον τα SOFC’s µπορεί να εισαχθούν για χρήση και σε αστικές περιοχές, όπου παράλληλα µε την παραγόµενη ηλεκτρική ενέργεια, είναι δυνατόν να αξιοποιηθεί και η εκλυόµενη θερµική ενέργεια για θέρµανση χώρων, αυξάνοντας συνολικά την αποτελεσµατικότητά τους. Ένα από τα µειονεκτήµατα που εµφανίζονται κατά την µακρόχρονη λειτουργία ενός «State of the art» κελίου καυσίµου αποτελούµενο από Ni/YSZ-κεραµοµεταλλικό (άνοδος) – YSZ (ηλεκτρολύτη) – LaMnO3 περοβσκίτης (κάθοδος) – LaCrO3 περοβσκίτης (συνδέτης) είναι η υποβάθµιση της απόδοσής του, η οποία µεταξύ άλλων οφείλεται και στην αστάθεια της µικροδοµής του κεραµοµεταλλικού ηλεκτροδίου της ανόδου, λόγω συσσωµάτωσης της µεταλλικής φάσης. Στόχος της εργασίας ήταν η βελτίωση της ευστάθειας της µικροδοµής, καθώς και η διερεύνηση της δυνατότητας ελάττωσης του ποσοστού συµµετοχής της µεταλλικής φάσης στο κεραµοµεταλλικό υλικό του ηλεκτροδίου της ανόδου, χωρίς σηµαντική απώλεια σε ηλεκτρική αγωγιµότητα. Για τον σκοπό αυτό παρασκευάσθηκαν, χαρακτηρίσθηκαν και ελέγχθηκαν οι ιδιότητες µικτών κεραµικών οξειδίων επιλεγµένων συνθέσεων του τριµερούς συστήµατος ZrO2-Y2O3-TiO2 (η Cr2O3) καθώς και τα αντίστοιχα κεραµοµεταλλικά Ni/ZrO2-Y2O3-TiO2 µε προσθήκη 30,40 και 45 vol% Ni. Aπό τα αποτελέσµατα προέκυψε ότι σε θερµοκρασία πύρωσης 1400ºC σχηµατίζονται µικτά οξείδια µε την κυβική δοµή του πλέγµατος φθορίτη και συντελεστή θερµικής διαστολής αντίστοιχο του ηλεκτρολύτη (YSZ). Η ηλεκτρική τους αγωγιµότητα σε ατµόσφαιρα Ar+4%H2 είναι µικτού τύπου (ιοντική + ηλεκτρονιακή), όµως λόγω της χαµηλής απόλυτης τιµής στην θερµοκρασιακή περιοχή λειτουργίας του κελίου καυσίµου (900-1000ºC) δεν προσφέρονται για χρήση αυτούσια, ως κεραµικές άνοδοι. ΠΕΡΙΛΗΨΗ-ABSTRACT 6 Από πειράµατα διαβροχής στο σύστηµα Ni σε επαφή µε τα µικτά οξείδια προέκυψε ότι η παρουσία TiO2 βελτιώνει την συνάφεια και ως εκ τούτου την ισχύ του δεσµού στην διεπιφάνεια µετάλλου/κεραµικού. Η βελτίωση των διεπιφανειακών ιδιοτήτων έχει σαν αποτέλεσµα των ελάττωση του συντελεστού διαστολής των κεραµεταλλικών και την καλλίτερη µηχανική προσαρµογή τους στον ηλεκτρολύτη (YSZ).Επίσης, λόγω της µείωσης του ρυθµού συσσωµάτωσης των σωµατιδίων της µεταλλικής φάσης, οι τιµές της ηλεκτρικής αγωγιµότητας των κεραµοµεταλλικών παραµένουν σε υψηλά επίπεδα και µετά από µακροχρόνια παραµονή σε συνθήκες λειτουργίας (1000ºC, 1000h). Πρώτες ηλεκτροχηµικές µετρήσεις σε κελία καυσίµου µε κεραµοµεταλλική άνοδο, αποτελούµενη από επιλεγµένη σύνθεση µικτού οξείδίου του τριµερούς συστήµατος ως κεραµικής συνιστώσας, έδωσαν ενθαρρυντικά αποτελέσµατα αφήνοντας σηµαντικά περιθώρια για επίτευξη ικανοποιητικών επιδόσεων, µε βελτίωση του τρόπου κατασκευής. / Within the research framework for the development of alternative, friendly to the environment methods for the production of energy, significant effort is focusing on the SOFC’s (Solid Oxide Fuel Cell’s) technology. Due to their low pollutant emissions fuel cells can be applied inside civil areas were the electrical power can be used together with the thermal energy generated by the cell, increasing the total performance of the device. The “state of the art” fuel cell structure is the anode electrode (Ni/YSZ cermet), the electrolyte (YSZ), the cathode electrode (LaMnO3 perowskite) and the interconnector (LaCrO3 perowskite). One of the disadvantages of fuel cells is the performance degradation due to the instability of the YSZ/Ni anode electrode microstructure caused by metal phase sintering. This work aims to the improvement of microstructure stability as well as the possibility of reducing the amount of the metallic phase to the anode cermet without affecting its electrical properties. New ceramic materials of the ternary system ZrO2-Y2O3-TiO2 (or Cr2O3) were produced and characterized as well as their corresponding cermets Ni/ZrO2-Y2O3-TiO2 by the addition of 30,40 and 45 vol% Ni. After calcination at 1400ºC mixed oxides are formed having cubic fluorite crystal structure and similar thermal expansion properties to the YSZ ceramic oxide. The electrical conductivity in reducing atmosphere Ar+4%H2 is of electronic and ionic type but due to the low values in the working temperature range of a fuel cell (900-1000ºC) they cannot be used independently as anode materials. Wetting experiments of the system Ni in contact to those mixed oxides showed that TiO2 presence enhances the adherence and the bond strength at the metal ceramic interface. Improvement of the interfacial properties results to the decrease of cermets thermal expansion improving in this way the mechanical adjustment of the anode to the electrolyte. Also due to the decrease of the sintering tendency of the metallic phase particles, the electrical conductivity values remain at high values after long term annealing at high temperature (1000ºC, 1000h). Early electrochemical tests performed to fuel cells having a selected anode material showed encouraging results leaving space for improvement especially to the construction methods used in order to achieve satisfactory performance.
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Pt Nanophase supported catalysts and electrode systems for water electrolysis.Petrik, Leslie Felicia. January 2008 (has links)
<p>In this study novel composite electrodes were developed, in which the catalytic components were deposited in nanoparticulate form. The efficiency of the nanophase catalysts and membrane electrodes were tested in an important electrocatalytic process, namely hydrogen production by water electrolysis, for renewable energy systems. The activity of electrocatalytic nanostructured electrodes for hydrogen production by water electrolysis were compared with that of more conventional electrodes. Development of the methodology of preparing nanophase materials in a rapid, efficient and simple manner was investigated for potential application at industrial scale. Comparisons with industry standards were performed and electrodes with incorporated nanophases were characterized and evaluated for activity and durability.</p>
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Nouveaux matériaux d’anode et cellules architecturées pour électrolyseur à haute température / Innovative anode materials and architectured cells for high temperature steam electrolysis operationOgier, Tiphaine 10 December 2012 (has links)
Afin d’améliorer les performances électrochimiques de cellules d’électrolyse de la vapeur d’eau à haute température (EVHT), de nouveaux matériaux d’électrode à oxygène de typeLn2NiO4+δ (Ln = La, Pr ou Nd), Pr4Ni3O10±δ et La0,6Sr0,4Fe0,8Co0,2O3-δ ont été étudiés. Ces composés ont été sélectionnés pour leurs propriétés de conduction mixte électronique et ionique. Après la caractérisation de leurs propriétés physico-chimiques, les matériaux ont été mis en forme au sein de demi-cellules symétriques, en intercalant une couche d’interface fine à base de cérine entre l’électrode et l’électrolyte de zircone yttriée. Cette architecture contribue à la diminution de la résistance de polarisation de l’électrode (RP <0,1 Ω.cm2 à 800°C) et de la surtension anodique. Un modèle électrochimique a été développé afin de décrire et d’analyser les courbes de polarisation expérimentales.L’électrode présentant les plus faibles surtensions, Pr2NiO4+δ, a été sélectionnée et caractérisée au sein de cellules complètes à cermet support. En fonctionnement EVHT à800°C, une densité de courant élevée a été obtenue, de l’ordre de i = -0,9 A.cm-2 pour une tension de cellule de 1,3V et un taux de conversion d’environ 60%. / In order to improve the electrochemical performances of cells for high temperature steam electrolysis (HTSE), innovative oxygen electrode materials have been studied. The compounds Ln2NiO4+δ (Ln = La, Pr or Nd), Pr4Ni3O10±δ and La0.6Sr0.4Fe0.8Co0.2O3-δ have been selected for their mixed electronic and ionic conductivity. First, their physical and chemical properties have been investigated. Then, the electrodes were shaped on symmetrical half cells,adding a thin ceria-based interlayer between the electrode and the yttria doped zirconia-based electrolyte. These architectured cells lead to low polarization resistances (RP< 0.1 Ω.cm2 at 800°C) as well as reduced anodic over potentials . An electrochemical model has been developed in order to describe and analyze the experimental polarization curves.The electrode with the lower overpotential, i.e. Pr2NiO4+δ, has been selected and characterized into complete cermet-supported cells. Under HTSE operation, at 800°C, a high current density was measured, close to i = -0.9 A.cm-2 for a cell voltage equals to 1.3 V, the conversion rate being about 60%.
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