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Catalisadores à base de metais não nobres formados por carbeto de tungstênio/carbono com estruturas FeNx e N/C para reação de redução do oxigênio / Catalysts based on non-noble metals formed by tungsten carbide/carbon with FeNx and N/C structures for oxygen reduction reactionUlisses Alves do Rêgo 13 July 2018 (has links)
Este trabalho teve como objetivo investigar eletrocatalisadores de baixo custo à base de carbeto de tungstênio, carbono e ferro submetidos a diferentes processos de nitretação quanto à atividade catalítica para reação de redução do oxigênio (RRO) nos eletrólitos ácido e alcalino. Os catalisadores foram divididos em três séries distintas, a primeira compreendendo aqueles onde houve variação da carga de carbeto de tungstênio em relação ao suporte de carbono, que foram impregnados com o complexo Fe2+(2,4,6-Tris(2-piridil)-1,3,5-Triazina)2, [Fe(TPTZ)2]2+ e tratados em duas temperaturas diferentes, 700 e 800 oC em atmosfera de nitrogênio. Na segunda série foi mantida constante a carga de carbeto de tungstênio (30% de W/C, m/m) sendo que esta mescla foi preparada usando carbonos dopados previamente com três fontes distintas de nitrogênio (HNO3, NH3 e HNO3/NH3); isto foi seguido pela incorporação do complexo Fe[TPTZ]2+ e pelos mesmos tratamentos térmicos acima mencionados. Na terceira série, os eletrocatalisadores foram preparados com três tipos de carbonos (Vulcan, Ketjenblack e Monarch), aos quais foi incorporado o complexo Fe[TPTZ]2+, seguido pelo tratamento térmico a 800 °C em atmosfera de nitrogênio e então por dopagem com amônia a 950 °C. As três séries de eletrocatalisadores sintetizados neste trabalho foram cuidadosamente caracterizadas por espectroscopia infra-vermelho e UV-Visível, difratometria de raio-x, microscopia eletrônica de transmissão, energia dispersiva de raios-x, espectroscipia Raman, espectroscopia fotoeletrônica de raios-x. As investigações eletroquímicas foram realizadas por voltametria cíclica (VC) e pelo levantamento de curvas de polarização de estado estacionário para a RRO, usando a técnica de eletrodo de disco/anel rotatório, com materiais catalíticos formando filmes finos depositados no eletrodo de disco. Nas três séries de catalisadores foram desenvolvidos materiais com bom desempenho para a RRO. Nos estudos da primeira série de catalisadores, notou-se que o material mais ativo foi aquele formado por WC-FeNx/C com 30 % de W/C e 5% de Fe pirolisado a 800 °C. Na segunda série foi observado que os desempenhos dos catalisadores variaram de acordo com o tipo de protocolo de nitretação, presença de ferro e temperatura de tratamento térmico. Em eletrólito alcalino, os eletrocatalisadores apresentaram maiores desempenhos, que resultaram bastante próximos em relação ao do catalisador de Pt dispersa em carbono usado como referência. Na terceira série de eletrocatalisadores investigados, verificou-se que o melhor desempenho obtido foi com o catalisador com carbono Monarch com amônia, cuja atividade catalítica resultou superior à dos demais, devido ao maior número de estruturas ativas FeNx e N/C formadas pelo tratamento com amônia. Os resultados nos meios ácido e alcalino para a primeira e segunda séries de eletrocatalisadores sugerem a ocorrência de um mecanismo indireto (2e- + 2e-), ou seja, em meio ácido (alcalino) primeiro o O2 reduz para H2O2 (HO2 ) e depois de H2O2 (HO2 ) para H2O. Os sítios predominantemente envolvidos na catálise da reação são WC e FeNx em meio ácido e WC e N/C em meio alcalino. Finalmente, para a terceira série de eletrocatalisadores o mecanismo reacional em meio ácido envolve um mecanismo direto de 4e-, com participação importante dos sítios ativos de Fe-N2. / This work aims to investigate low cost electrocatalysts based on tungsten carbide, carbon and iron submitted to different nitriding processes for the catalytic activity for the oxygen reduction reaction (ORR) in acid and alkaline electrolytes. The catalysts were divided into three distinct series, the first one comprising those with different tungsten carbide loads with respect to the carbon support, which were impregnated with the Fe2+ (2,4,6-Tris (2-pyridyl) - 1,3,5-triazine)2, [Fe (TPTZ)]2+, complex and treated at two different temperatures, 700 and 800 oC in nitrogen atmosphere. In the second series, the tungsten carbide load (30% W/C, m/m) was kept constant but this mixture was prepared using previously doped carbons using three different sources of nitrogen (HNO3, NH3 and HNO3/NH3); this was followed by the incorporation of the Fe[TPTZ]2+ complex and by the same heat treatments as mentioned above. In the third series, the electrocatalysts were prepared with three carbon types (Vulcan, Ketjenblack and Monarch), to which the Fe[TPTZ]2+ complex was added, followed by heat treatment at 800 °C under nitrogen and then by nitriding using a flow of ammonia at 950 °C. The three series of electrocatalysts synthesized in this work were carefully characterized by infra-red and UV-Visible spectroscopy, x-ray diffraction, transmission electron microscopy, x-ray energy dispersive, Raman spectroscopy, x-ray photoelectron spectroscopy. The electrochemical investigations were performed by cyclic voltammetry (CV) and by measurements of steady-state polarization curves for ORR using rotating ring-disc electrode technique, with catalytic materials forming thin films deposited on the disc. In the three catalyst series, materials with good performance for the ORR were developed. In the studies of the first series of catalysts, it was seen that the most active material was that formed by WC-FeNx/C with 30%W/C and 5% Fe pyrolyzed at 800 ° C. In the second series it was observed that the performances of the catalysts varied according to the type of nitriding protocol, presence of iron and temperature of heat treatment. The electrocatalysts showed higher performances in alkaline electrolyte, which were very close to that of a reference Pt/C catalyst. In the third series of electrocatalysts, the best performance was obtained with the Monarch carbon catalyst heat-treated with ammonia, whose catalytic activity was higher than all others, due to the greater number of FeNx and N/C active structures formed by the treatment with ammonia. The results in acidic and alkaline conditions for the first and second series of electrocatalysts suggest the occurrence of an indirect ORR mechanism (2e- + 2e-), that is, in acid (alkaline) media first O2 is reduced to H2O2 (HO2) followed by the reduction of H2O2 (HO2). The active sites predominantly involved in the reaction electrocatalysis are WC and FeNx in acid media and WC e N/C in alcaline media. Finally, for the third series of electrocatalysts, the acidic reaction involves a direct 4e- mechanism, having important participation of the Fe-N2 active sites.
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Réponse optique de nano-objets uniques d’argent : couplage plasmonique et photo-oxydation / Optical response of single silver nano-objects : plasmonic coupling and photo-oxidationGrillet, Nadia 04 July 2011 (has links)
La réponse optique de nanostructures métalliques est caractérisée par une amplification locale du champ électromagnétique appelée Résonance Plasmon de Surface (RPS) reliée à leur nature et leur morphologie. Pour étudier la réponse optique d’une nanoparticule unique, un dispositif ultra-sensible de spectroscopie à modulation spatiale utilisant une source de lumière blanche a été développé : il permet de mesurer la section efficace d’extinction absolue de nano-objets uniques sur un large domaine spectral (300-900 nm). Des images de microscopie électronique à transmission peuvent être obtenues indépendamment sur les mêmes objets. On a ainsi une corrélation directe entre la morphologie des nanoparticules et leur signature optique. Ce travail de thèse a permis d’une part de mettre en évidence les paramètres qui entrent en jeu dans le processus de vieillissement de nanoparticules uniques d’argent sous éclairement. En particulier, l’étude de nanocubes d’argent révèle une « sphérisation » et une photo-oxydation au cours du temps due à la partie UV du spectre. D’autre part, des mesures réalisées sur des doublets de nanocubes d’argent en interaction ont montré l’importance de la morphologie à l’interface entre les deux nanoparticules sur le couplage plasmonique. Pour une excitation lumineuse longitudinale, on observe, outre le décalage de la RPS vers les basses énergies lorsque la distance interparticule diminue, un dédoublement de cette bande de résonance. Des calculs théoriques réalisés avec la méthode DDA ont permis de corréler ce phénomène de dédoublement à des variations de courbure de surface dans la zone interparticule liées principalement au rognage des arêtes des cubes / The optical properties of noble metal nanoparticles are known to be dominated by the localized surface plasmon resonance (SPR) which is highly sensitive to the size of the particles, their shape, their environment, and eventually their chemical composition in the case of mixed systems. In order to study the optical response of a single supported metallic nanoparticle, a high sensitive spectroscopic setup using a white lamp (300-900 nm) has been developed in a transmission measurement configuration. This technique, the Spatial Modulation Spectroscopy, aims to detect the overall extinction of light by a nanoparticle. Moreover, the coupling of this technique with the direct observation of the particles by Transmission Electron Microscopy allows to get an unambiguous description of their optical response in relation with their exact morphology. In this work, the optical response of single silver nano-objects has been correlated with their morphology and their structure at a sub-nanometer scale. Time evolution of the optical response of single silver nanocubes under illumination was first investigated. We observed a “spherization” and a photo-oxidation due to the UV part of the light. Moreover, we studied pairs of cubic silver nanoantennas that showed a huge sensitivity of their optical response with the interparticle distance and their morphology. Indeed, the SPR is red-shifted with decreasing interparticle distance. One can also observe a striking splitting of the resonance for very low interparticle distances. Preliminary DDA calculations seem to show that the radius of curvature at the corners and edges of both cubes plays a key role in the splitting of the resonance
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Two-Dimensional Core-Shelled Porous Hybrids as Highly Efficient Catalysts for Oxygen Reduction ReactionYuan, Kai, Zhuang, Xiaodong, Fu, Haiyan, Brunklaus, Gunther, Forster, Michael, Chen, Yiwang, Feng, Xinliang, Scherf, Ullrich 07 May 2018 (has links) (PDF)
No description available.
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Preparation, Processing and Characterization of Noble Metal Nanoparticle-based AerogelsHerrmann, Anne-Kristin 10 July 2014 (has links)
New challenges in nanotechnology arise in the assembly of nanoobjects into three-dimensional superstructures, which may carry synergetic properties and open up new application fields. Within this new class of materials nanostructured, porous functional metals are of great interest since they combine high surface area, gas permeability, electrical conductivity, plasmonic behavior and size-enhanced catalytic reactivity. Even though a large variety of preparation pathways for the fabrication of porous noble metals has already been established, several limitations are still to be addressed by research developments.
The new and versatile approach that is presented in this work makes use of a templatefree self-assembly process for the fabrication of highly porous, metallic nanostructures. Thereby, nanochains are formed by the controlled coalescence of noble metal NPs in aqueous media and their interconnection and interpenetration leads to the formation of a self-supported network with macroscopic dimensions. Subsequently, the supercritical drying technique is used to remove the solvent from the pores of the network without causing a collapse of the fragile structure. The resulting highly porous, low-weighted, three-dimensional nanostructured solids are named aerogels. The exceptional properties of these materials originate from the conjunction of the unique properties of nanomaterials magnified by macroscale assembly.
Moreover, the combination of different metals may lead to synergetic effects regarding for example their catalytic activity. Therefore, the synthesis of multimetallic gels and the characterization of their structural peculiarities are in the focus of the investigations. In the case of the developed preparation pathways the gelation process starts from preformed, stable colloidal solutions of citrate capped, spherical noble metal (Au, Ag, Pt, Pd) NPs. In order to face various requirements several methods for the initiation of the controlled destabilization and coalescence of the nanosized building blocks were developed and synthesis conditions were optimized, respectively. Multimetallic structures with tunable composition are obtained by mixing different kinds of monometallic NP solutions and performing a joint gel formation.
The characterization of the resulting materials by means of electron microscopy reveals the formation of a highly porous network of branched nanochains that provide a polycrystalline nature and diameters in the size range of the initial NPs. Furthermore, synthesis conditions for the spontaneous gel formation of glucose stabilized Au and Pd NPs were investigated. In order to gain a detailed knowledge of the structural properties of bimetallic aerogel structures a versatile set of characterization techniques was applied. A broad pore size distribution dominated by meso- and macropores and remarkably high inner surface areas were concluded from the N2 physisorption isotherms and density measurements. As investigated, a specific thermal treatment could be used to tune the ligament size of Au-Ag aerogels, whereas Au-Pd and Pt-Pd structures provide thermal stability under mild conditions.
Further investigations aimed to the enlightenment of the elemental distribution and phase composition within the nanochains of multimetallic gel structures. The different approaches provide complementary and consistent results. Phase analyses based on XRD measurements revealed separated phases of each metal in the case of Ag-Pd and Au-Pd aerogels. They further proved the possibility of temperature induced phase modifications that lead to complete alloying of Au and Pd. In addition, separated domains of Pt and Pd were established from the EXAFS analysis of the corresponding aerogel. STEM EDX high resolution elemental mappings confirmed the separated domains of different metals in the case of Au-Pd and Pt-Pd aerogels. Moreover, a complete interdiffusion and alloy formation of Au and Ag within the corresponding aerogel structure is suggested from STEM EDX results.
Finally, the presented investigations further promote the field of metallic aerogels by addressing the challenging issue of processability and device fabrication. Hybrid materials with organic polymers as well as various kinds of coatings on glass substrates and glassy carbon electrodes were prepared whereas the network structure was preserved throughout all processing steps. Moreover, it was illustrated that the NP-based aerogels carry metallic properties as expressed by their low Seebeck coefficients and high electrical conductivities.
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Two-Dimensional Core-Shelled Porous Hybrids as Highly Efficient Catalysts for Oxygen Reduction ReactionYuan, Kai, Zhuang, Xiaodong, Fu, Haiyan, Brunklaus, Gunther, Forster, Michael, Chen, Yiwang, Feng, Xinliang, Scherf, Ullrich 07 May 2018 (has links)
No description available.
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Darstellung von Edelmetallnanopartikeln und deren ÜberstrukturenBigall, Nadja-Carola 30 January 2009 (has links)
Zur Darstellung von Edelmetallnanopartikelüberstrukturen werden zunächst kolloidale Lösungen von Gold, Silber, Platin und Palladium synthetisiert. Dafür wird eine modifizierte Syntheseprozedur für Citrat stabilisierte Goldnanopartikel in wässriger Lösung unter Verwendung gleicher Konzentrationen auf die Systeme Silber, Platin und Palladium übertragen. Die Nanopartikellösungen werden mittels Absorptionsspektroskopie und Elektronenmikroskopie in mittlerer und hoher Auflösung charakterisiert. Die Platinnanopartikel werden verwendet, um mittels Keim vermitteltem Wachstum größere Platinnanopartikel darzustellen. Die resultierenden annähernd sphärischen Partikel haben eine sehr enge Größenverteilung mit einer Standardabweichung von drei bis sieben Prozent. Mit bis zu zwei Schritten des Keim vermittelten Wachstums können Partikel mit einem mittleren Durchmesser im Bereich von 10 bis 100 Nanometern hergestellt werden. Hochauflösende Elektronenmikroskopie zeigt, dass die Oberfläche der Partikel aus Platinkristalliten mit Durchmessern weniger Nanometer besteht, was zu einer Oberflächenrauhigkeit von drei bis zehn Nanometern führt. Mittels eines Kern-Schale-Modells werden Einzelteilchenextinktionsspektren berechnet, welche in sehr guter Übereinstimmung mit den experimentell bestimmten Extinktionsspektren des dispergierten Ensembles sind. Eine über weite Bereiche des sichtbaren Spektralbereichs lineare Abhängigkeit des Extinktionsmaximums vom Partikeldurchmesser wird beobachtet. Dadurch und zusammen mit der Einheitlichkeit der synthetisierten Platinsphären eröffnen sich Anwendungsmöglichkeiten im Bereich der Photonik, der Nanooptik und der oberflächenverstärkten Ramanspektroskopie. Geordnete Überstrukturen der Edelmetallnanopartikel können durch Infiltrieren von Templaten aus Block-Copolymer-Filmen mit wässriger Nanopartikellösung synthetisiert werden. In Abhängigkeit von der Vorbehandlung der Polymerfilme werden entweder zweidimensional periodische Anordnungen mit einer Periodizität von weniger als 30 Nanometern oder Fingerabdruck ähnliche Anordnungen mit einem Rillenabstand im selben Größenbereich hergestellt. Durch Entfernen des Polymers entstehen ein- bzw. zweidimensionale Anordnungen aus Platinnanodrähten bzw. -Nanopartikeln auf einem Siliziumwafer. Diese hochgeordneten Strukturen sind von fundamentalem Interesse für die Entwicklung von nanometerskaligen Schaltkreisen, Sensoren und als Substrate für die oberflächenverstärkte Ramanspektroskopie. Für die Herstellung ungeordneter Überstrukturen werden zwei unterschiedliche Ansätze gewählt: direkte Destabilisierung von Nanopartikellösungen, welche zu Hydrogelen und durch Trocknung zu Aerogelen führt, und Immobilisierung von Nanopartikeln auf einem in die Lösung implantierten Pilzmycel. Aus Gold-, Silber- und Platinnanopartikeln werden monometallische Hydro- und Aerogele synthetisiert. Unterschiedliche Destabilisierungsmittel sowie unterschiedliche Methoden zur Aufkonzentration der Nanopartikellösungen werden getestet. Abhängig von der Methode werden gelartige Überstrukturen mit teilweise komplexen Morphologien aus hierarchischen Anordnungen von Primär-, Sekundär-, Tertiärpartikeln beobachtet. Bimetallische Hydro- und Aerogele können aus Mischungen von Gold- oder Platin- mit Silbernanopartikellösungen hergestellt werden. Hochauflösende TEM-Aufnahmen zeigen ein polykristallines Netzwerk aus 2 bis 10 Nanometer dicken Drähten. Erste BET-Messungen zeigen, dass die Gold-Silber-Netzwerke eine Oberfläche von etwa 48 m2/g besitzen. Diese Systeme aus monometallischen und bimetallischen Nanopartikeln stellen erste Ansätze für hochporöse templatfreie Hydro- und Aerogele dar und besitzen großes Potential für den Einsatz in der heterogenen Gasphasenkatalyse, da fast die gesamte Oberfläche aus Übergangsmetall besteht. Es wird für eine Auswahl an unterschiedlichen Pilzen gezeigt, dass deren Wachstum direkt in den synthetisierten Nanopartikellösungen möglich ist. Ohne weitere Funktionalisierung findet eine Anlagerung von Nanopartikeln auf der Pilzoberfläche statt. Starke Variationen in den Affnitäten verschiedener Pilze zu den unterschiedlichen Metallnanopartikeln werden beobachtet. Auch werden Unterschiede der Nanopartikelaffnität mit Variation der Morphologie innerhalb desselben Hybridsystems beobachtet. Ein Platin-Pilz-Hybrid wird in wässriger Lösung erfolgreich als Katalysator einer Redoxreaktion getestet. Solche Hybridstrukturen besitzen ebenso wie die oben beschriebenen Aerogele großes Potential für den Einsatz in der heterogenen Katalyse, wobei die Verwendung von Pilzmycel als Trägermaterial eine kostengünstige Darstellung größerer Katalysatormengen ermöglichen könnte.
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Functional Noble Metal, Bimetallic And Hybrid Nanostructures By Controlled Aggregation Of Ultrafine Building BlocksHalder, Aditi 07 1900 (has links)
Functional nanomaterials are gaining attention due to their excellent shape and size dependent optical, electrical and catalytic properties. Synthesizing nanoparticles is no longer novel with the availability of a host of synthesis protocols for a variety of shapes and sizes of particles. What is currently needed is an understanding the fundamentals of shape and size controlled synthesis to produce functional nanomaterials that is simple and general. In addition to simple metallic nanostructures, synthesizing bimetallic and hybrid nanostructures are important for applications. Instead of trying to add functionality to the preformed nanomaterials, it is advantageous to look for cost effective and general synthetic protocols that can yield bimetallic, hybrid nanostructures along with the shape and size control.
In this dissertation, a novel synthetic protocol for the synthesis of ultrfine single crystalline nanowires, metallic and bimetallic nanostructures and hybrid nanostructures has been investigated. The key point of the synthesis is that all different functional nanostructures are achieved by the use of noble metal intermediates in organic medium without phase transfer reagents. The roles of capping agents, oriented attachment and aggregation phenomenon have been studied in order to understand the formation mechanisms. Along with the synthesis, formation mechanisms, the optical and catalytic properties of the functional, noble metal, bimetallic and hybrid nanostructures have been studied.
The entire thesis based on the results and findings obtained from the present investigation is organized as follows:
Chapter I provides a general introduction to functional nanomaterials, their properties and some general applications, along with a brief description of conventional methods for size and shape-controlled synthesis.
Chapter II deals with the materials and methods which essentially gives the information about the materials used for the synthesis and the techniques utilized to characterize the materials chosen for the investigation.
Chapter III presents a novel method of for synthesizing noble metals nanostructures starting from an intermediate solid phase. The method involves the direct synthesis of noble metal intermediates in organic medium without the use of any phase transfer reagent. Controlled reduction of these intermediates leads to the formation of ultrafine nanocrystallite building blocks. Controlled aggregation of the nanocrystallites under different conditions leads to the formation of different nanostructures ranging from single crystalline nanowires to porous metallic clusters. In this chapter, the details of synthesis of the intermediate phase of gold are presented. This intermediate phase is the rocksalt phase of AuCl that has been experimentally realized for the first time. Manipulation of the AuCl nanocubes leads to the formation of a variety of nanostructures of Au starting from hollow cubes to extended porous structures. Mechanistic details of the formation of the intermediate and the nanostructures are presented in this chapter.
Chapter IV deals with the symmetry breaking of an FCC metal (gold) by oriented attachment of metal nanoparticles by the preferential removal of capping agent from certain facets and followed by the attachment of gold nanoparticles along those bare facets. This kind of oriented attachment leads to the formation of 1D nanostructures with high aspect ratios. In this chapter, the synthesis, characterisation, formation mechanism and optical properties of high aspect ratio, molecular scale single crystalline gold nanowires has been described. This represent the first ever successful method to produce ultrafine 1D metallic nanostructures approaching molecular dimensions.
Chapter V deals with the formation of hybrid nanostructures by attaching the cubic intermediate phase to a substrate like carbon nanotubes followed by the reduction of the attached intermediates on the tubes. The Pt intermediates have been synthesized and attached on the wall of functionalized CNTs and reduced. The PtCNT nanocomposites been characterized by several spectroscopic and microscopic techniques. The electrocatalytic activity of these nanocomposites towards the methanol oxidation has also been investigated. The composites exhibit high catalytic activity and good long term performance. The presence of functional groups on the CNT surface overcomes some of the limitations of current single metal catalysts that suffer from CO poisoning.
Chapter VI deals with the formation of palladium nanostructures ranging from nanoparticles to hierarchical aggregates by controlled aggregation of nanoparticles in an organic medium that is tuned by the dielectric constant of the system. A crystalline intermediate of palladium salt has been synthesized and this intermediate of palladium has been used as the precursor solution for the synthesis of palladium nanostructures. The formation mechanism of the nanoporous Pd cluster is investigated using the modified DLVO approach. The catalytic efficiency of the Pd nanostructures has been investigated using the reduction of pnitrophenol and electrocatalytic hydrogen storage as model reactions.
Chapter VII discusses the possibility of achieving functional bimetallic alloys by simultaneous reduction of the cubic intermediate of two different metals with experimental evidences. The synergistic effect of the two different metals gives rise to better catalytic activity. This chapter mainly deals with the synthesis of bimetallic porous nanoclusters of goldpalladium and goldplatinum in an organic medium. Detailed microstructural and spectroscopic characterisation of the bimetallic nanoclusters has been carried out and their electrocatalytic performance, morphological stability also investigated.
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Plasma modification on carbon black surface: From reactor design to final applicationsTricàs Rosell, Núria 01 June 2007 (has links)
El present treball es basa en l'estudi de la modificació de la superfície del negre de carboni (NC) per mitjà de tècniques de plasma. Tot i que aquest tipus de tractament s'utilitza de manera comú sobre superfícies planes, tanmateix encara existeixen problemes a l'hora de treballar en materials en pols degut a la dificultat que suposa la seva manipulació. En aquest treball s'ha modificat NC tant per tècniques de plasma a baixa pressió com per mitjà de tècniques de plasma atmosfèric. Per tal d'assolir aquest objectiu s'han posat a punt tres reactors de plasma capaços de modificar aquest tipus de material; dos reactors treballen a baixa pressió mentre que el tercer es tracta d'un equip a pressió atmosfèrica.Els sistemes de plasma a baixa pressió utilitzats han estat un reactor down-stream i un reactor de llit fluiditzat. Ambdós sistemes utilitzen un generador de radio freqüències a 13,56MHz per tal de general el plasma. Tots dos sistemes han estat optimitzats per la modificació de materials en pols. En el cas del reactor down-stream, s'ha estudiat a posició d'entrada del gas reactiu, la potència del generador i el temps de modificació per a tres tipus de tractament: oxigen, nitrogen i amoníac. En el cas del reactor de llit fluiditzat, els paràmetres que s'han estudiat han estat la distància entre la pols i la zona de generació de plasma, la mida de la partícula i la porositat de la placa suport.Pel que fa a la modificació mitjançant la utilització de plasma atmosfèric, s'ha dissenyat un sistema que permet utilitzar una torxa de plasma atmosfèric comercial (Openair® de Plasmatreat GmbH) per tal de modificar materials en pols. Aquest sistema consisteix en un reactor adaptable a la torxa de plasma atmosfèric on té lloc la modificació, un sistema d'introducció de la pols dins de la zona de reacció així com també un sistema de refredament i col·lecció del material modificat que conjuntament permeten un funcionament quasi-continu del tractament.S'ha utilitzat el reactor down-stream i el reactor a pressió atmosfèrica per tal de modificar tres tipus diferents de negre de carboni (N134, XPB 171 i Vulcan XC-72). D'altra banda, s'ha grafititzat i extret el N134 prèviament a la modificació per tal de realitzar un estudi sobre la influència de l'estructura superficial així com també de la presència d'impureses sobre la superfície del NC. L'oxidació i l'augment de nitrogen en superfície han estat les dues modificacions que s'han estudiat principalment per tal de comparar el resultat obtingut per les tècniques presentades.El NC s'ha caracteritzat mitjançant diverses tècniques analítiques per tal de poder obtenir informació sobre els canvis produïts durant la modificació per plasma. Aquestes tècniques inclouen superfície específica, XRD, WAXS, STM per tal d'estudiar els canvis en la seva morfologia i estructura de la superfície. D'altra banda, per tal d'estudiar els canvis en la composició química s'han emprat mesures de pH, valoracions àcid/base i XPS.Finalment, alguns dels negres de caboni modificats han estat seleccionats per tal de ser avaluats en aplicacions finals tal i com són el reforçament d'elastòmers i la seva activitat vers la reducció d'oxigen utilitzada en les PEMFC per tal d'eliminar els metalls nobles. En el primer cas, s'ha estudiat l'efecte sobre la cinètica i el mecanisme de vulcanització del negre de carboni modificat mitjançant el plasma atmosfèric. Aquest estudi s'ha dut a terme utilitzant dues tècniques complementaries com són les corbes reomètriques i la vulcanització de molècules model (MCV). També s'han realitzat mesures d'adsorció de polímer sobre el NC i Bound Rubber per tal d'estudiar la interacció polímer-càrrega la qual presenta una gran influència en les propietats finals dels materials. D'altra banda, s'ha estudiat també la capacitat del NC modificat vers a la reducció d'oxigen a partir de voltametria cíclica i s'han determinat les propietats del NC que poden influir de manera rellevant en l'activitat cataítica final del NC per a aquesta reacció. Tot i que es necessari fer una preparació posterior al tractament de plasma per a aquesta aplicació, el material final pot contribuir notablement a la eliminació de metalls nobles com a catalitzadors de reducció d'oxigen en les Piles de Combustible. / The present works deals with plasma modification of carbon black (CB). Although this type of treatment is widely used on flat surfaces handling problems should be overcome in order to treat powders as CB. In this study CB has been modified both by means of low-pressure and atmospheric pressure non-equilibrium plasmas. In order to accomplish this objective three different plasma reactors have been set-up; two at low pressure and one at atmospheric pressure working conditions.Low pressure plasma reactors utilised in this work consist in a down-stream and a fluidised bed system working at Radio Frequency generation power (RF 13,56 MHz). Both reactors have been optimized to treat powder materials. For the down-stream reactor, position of the reactive gas inlet, and treatment conditions such as generator power and time have been studied for oxygen, nitrogen and ammonia treatments. For the fluidized bed reactor the distance of the powder sample to the plasma generation zone, particle size and support porosity have been taken into account. Concerning atmospheric plasma, a device has been set up in order to adapt a commercial plasma torch (Openair® from Plasmatreat GmbH), for powder modification. An adaptable reactor, a method to introduce the powder in the plasma zone as well as a collecting system had been developed in order to obtain a quasi-continuous modification treatment.Three types of CBs, N134, XPB 171 and Vulcan XC-72 have been modified in both the down-stream and the atmospheric plasma system. Graphitization and extraction of N134 were also carried out before plasma modification in order to study the effect of both impurities and surface structure of the CB during plasma modification. Surface oxidation and nitrogen enrichment were the two main studied treatments in both systems which allowed comparing their performances.Unmodified and Modified CBs have been characterised from several points of view. Specific surface area, XRD, WAXS and STM have been used in order to study morphological and surface structure changes. On the other hand, pH measurements, acid/base titration and XPS were employed in order to study the surface chemistry composition changes that had taken place during plasma modification. Some of the modified CB grades were selected in order to be tested in final applications such as rubber reinforcement and oxygen reduction non-noble metal catalyst for PEMFC. In the first case, the effect of atmospheric plasma treatment on the vulcanization kinetics and mechanism has been evaluated both by rheometre curves and the model compounding approach. Studies about the polymer-filler interaction have been also carried out by calculating bound rubber and adsorption from polymer solution. Last but not least, plasma modification capacity to enhance the oxygen reduction activity to obtain non-noble metal catalysts for PEMFC has been evaluated after the correspondent preparation. Oxygen reduction activity has been studied by means of cyclic voltammetry. The main CB properties which could play an important role in such applications have been analyzed.
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Noble Metal And Base Metal Ion Substituted Ceo2 And Tio2 : Efficient Catalysts For Nox AbatementRoy, Sounak 12 1900 (has links)
In recent times, as regulations and legislations for exhaust treatment have become more stringent, a major concern in the arena of environmental catalysis is to find new efficient and economical exhaust treatment catalysts. Chapter 1 is a review of the current status of various NOx abatement techniques and understanding the role of “auto-exhaust catalysts” involved therein. Chapter 2 presents the studies on synthesis of ionically substituted precious metal ions like Pd2+, Pt2+ and Rh3+ in CeO2 matrix and their comparative three-way catalytic performances for NO reduction by CO, as well as CO and hydrocarbon oxidation. Ce0.98Pd0.02O2- showed better catalytic activity than ionically dispersed Pt or Rh in CeO2. The study in Chapter 3 aims at synthesizing 1 atom% Pd2+ ion in TiO2 in the form of Ti0.99Pd0.01O2- with oxide ion vacancy. A bi-functional reaction mechanism for CO oxidation by O2 and NO reduction by CO was proposed. For NO reduction in presence of CO, the model based on competitive adsorption of NO and CO on Pd2+, NO chemisorption and dissociation on oxide ion vacancy fits the experimental data. The rate parameters obtained from the model indicates that the reactions are much faster over this catalyst compared to other catalysts reported in the literature. In Chapter 4 we present catalytic reduction of NO by H2 over precious metal substituted TiO2 (Ti0.99M0.01O2-, where M = Ru, Rh, Pd, Pt) catalysts. The rate of NO reduction by H2 depends on the reducibility of the catalysts. Chapter 5 presents the studies on reduction of NO by NH3 in presence of excess oxygen. 10 atom % of first row transition metal ions (Ti0.9M0.1O2-, where M = Cr, Mn, Fe, Co and Cu) were substituted in anatase TiO2 and TPD study showed that the Lewis and Bronsted acid sites are adsorption sites for NH3, whereas NO is found to dissociatively chemisorbed in oxide ion vacancies. The mechanism of the low temperature catalytic activity of the SCR and the selectivity of the products were studied to understand the mechanism by studying the by-reactions like ammonia oxidation by oxygen. A new catalyst Ti0.9Mn0.05Fe0.05O2- has shown low temperature activity with a broad SCR window from 200 to 400 °C and more selectivity than commercial vanadium-oxides catalysts. We attempted NO dissociation by a photochemical route with remarkable success. In Chapter 6 we report room temperature photocatalytic activity of Ti0.99Pd0.01O2- for NO reduction and CO oxidation by creating redox adsorption sites and utilizing oxide ion vacancy in the catalyst. The reduction of NO is carried out both in the presence and in the absence of CO. Despite competitive adsorption of NO and CO on the Pd2+ sites, the rate of reduction of NO is two orders of magnitude higher than unsubstituted TiO2. High rates of photo-oxidation of CO with O2 over Ti0.99Pd0.01O2- were observed at room temperature. In Chapter 7 the results are summarized and critical issues are addressed. Novel idea in this thesis was to see if both noble metal ions and base metal ions substituted in TiO2 and CeO2 reducible supports can act as better active sites than the corresponding metal atoms in their zero valent state.
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Gas Phase And Electrocatalytic Reaction Over Pt, Pd Ions Substituted CeO2, TiO2 Catalysts and Electronic Interaction Between Noble Metal Ions And The Reducible OxideSharma, Sudanshu 04 1900 (has links)
Among the various heterogeneous catalytic reactions three way catalysis (TWC), catalytic combustion of hydrogen, water gas shift reaction (WGS) and preferential oxidation of CO (PROX) in the hydrogen rich stream are some of the important reactions receiving the attention presently. Three-way catalysis (TWC) involves simultaneous removal of the three pollutants (i.e., CO, NOx, and HCs) from the automobile exhaust. Catalytic combustion of hydrogen by oxygen or hydrogen-oxygen recombination reaction is an industrially important reaction. It has variety of application such as in sealed lead acid batteries and nuclear reactors. Water gas shift (WGS) reaction is of specific importance to produce hydrogen from carbonaceous material. PROX is an important step to further purify hydrogen produced form WGS. Hydrogen purified using PROX can be directly fed to polymer electrolyte membrane fuel cells. By and large, noble metals Pt, Pd, Rh, Ru and some of their alloys are dispersed on oxide or high surface area carbon are the active catalysts. An alternative approach can be to make Pt2+, Pd2+, Rh3+, Ru4+ ions substituted in reducible support such as CeO2, Ce1-xTixO2-δ and TiO2 to increase the dispersion and bring down the cost. In this thesis we have followed this new approach and show that noble metal ionic catalysts are superior to noble metal nano particles.
In the 1st chapter we present an overview of heterogeneous catalysis and important heterogeneous catalytic reactions. Monolithic catalyst and various ways to coat catalysts for application have been reviewed. Metal-support interaction till date is also reviewed.
In the 2nd chapter, synthesis of noble metal ionic catalysts by solution combustion method is described. Coating of washcoat and active catalyst phase over ceramic honeycomb by a new combustion method is described. Solution combustion reaction and characterization of the catalyst by x-ray diffraction, x-ray photoelectron spectroscopy, temperature programmed reduction and reaction is given. We have fabricated experimental systems to carryout catalytic reaction and in this chapter they have been presented.
In the 3rd chapter, we report a new process of coating of active exhaust catalyst over -Al2O3 coated cordierite honeycomb. The process consists of (a) growing -Al2O3 on cordierite by solution combustion of Al(NO3)3 and oxylyldihydrazide (ODH) at 600 0C. Active catalyst phase, Ce0.98Pd0.02O2- is coated on - Al2O3 coated cordierite again by combustion of ceric ammonium nitrate and ODH with 1.2 10-3 M PdCl2 solution at 500 0C. In this way a coat layer over cordierite ceramic has been achieved and catalyst has the active sites in the form of Pd2+ ions rather than Pd metal. Weight of the active catalyst can be varied from 0.02 to 2 wt% which is sufficient but can be loaded even up to 12 wt% by repeating dip dry combustion [1]. Adhesion of catalyst to cordierite surface is via oxide growth on oxide ceramic which is very strong. 100 % conversion of CO is achieved below 80 oC at a space velocity of 880 h-1. At much higher space velocity of 21000h-1, 100 % conversion is obtained below 245 oC. Activation energy for CO oxidation is 8.4 kcal/mol. At a space velocity of 880 h-1 100% NO conversion is attained below 185 oC and 100 % conversion of ‘HC’(C2H2) below 220 oC. At the same space velocity 3-way catalytic performance over Ce0.98Pd0.02O2- coated monolith shows 100% conversion of all the pollutants below 220 o C with 15% excess oxygen. Catalytic activity of cordierite honeycomb coated by this new coating method for the oxidation of major hydrocarbons in exhaust gas is discussed further in this chapter. ‘HC’ oxidation over the monolith catalyst is carried out with a mixture having the composition, 470 ppm of both propene and propane and 870 ppm of both ethylene and acetylene with the varying amount of O2. 3-way catalytic test is done by putting hydrocarbon mixture along with CO (10000ppm), NO (2000ppm) and O2 (15000ppm). Below 350 oC full conversion is achieved [2]. A comparison of the results shows that Ce1-xPdxO2-δ far superior to other catalysts. In this method, handling of nano material powder is avoided.
In the 4th chapter we present a detailed study on the catalytic combustion of hydrogen by oxygen (hydrogen oxygen recombination reaction). Ever since Michel Faraday showed H2 + O2 recombination reaction over platinum metal plates, Pt metal has remained the only room temperature recombination catalyst. In search of an alternative catalyst, we discovered a new Pt free Ti0.99Pd0.01O2- compound which shows high rates of this reaction above 45 oC compared to Ce0.98Pt0.02O2-, Pt/Al2O3 and Pd/Al2O3. High rates of H2+O2 recombination over Pt and Pd ion respectively in CeO2 and TiO2 is due to the protonic type H2+ adsorption on Pt2+ or Pd2+ and dissociative chemisorption of O2 on the electron rich oxide ion vacancies [3]. In the case of Ce0.98Pt0.02O2-, H2/Pt ratio in a TPR experiment is ~2.3 at 0 oC. In the case of Ti0.99Pd0.01O2- also, H2 adsorption occurs below 0 oC and H2 / Pd ratio is ~2.2. Thus, more than 4-5 H atoms are adsorbed per metal ion. This is attributed to hydrogen spillover. H2 is known to be adsorbed as hydride ion (H-) over Pt, Pd, Rh, Ru, Os and Ir metals. Proton NMR studies of H2 adsorbed on Pd metal have shown upfield i.e. negative shift of 12 ppm with respect to TMS. We have studied proton NMR of Ti0.99Pd0.01O2- + H2 which show a downfield shift of 11.35 ppm confirming H+ or H2+ kind of species over Pd2+ ion in Ti0.99Pd0.01O2-. In Ce0.98Pt0.02O2- also H2 adsorption led to H2+ like species observed at 8 ppm and DFT calculations indeed showed H2+ kind species. H2+ is a precursor for dissociation and can readily induce O2 dissociation leading to high rates of recombination.
In the 5th chapter we report water gas shift reaction (WGS) and preferential oxidation of CO (PROX) over Ti0.99Pt0.01O2-, Ce0.83Ti0.15Pt0.02O2- and Ce0.98Pt0.02O2-δ.
The water gas shift reaction (WGS) is an important reaction to produce hydrogen. In this study, we have synthesized nano crystalline catalysts where Pt ion is substituted in the +2 state in TiO2, CeO2 and Ce1-xTixO2-δ. The catalysts have been characterized by X-ray diffraction and X-ray photoelectron spectroscopy (XPS) and it has been shown that Pt2+ ions in these reducible oxides of the form Ti0.99Pt0.01O2-, Ce0.83Ti0.15Pt0.02O2- and Ce0.98Pt0.02O2-δ are highly active. These catalysts were tested for the water gas shift reaction both in presence and absence of hydrogen. It is shown that Ti0.99Pt0.01O2- exhibits higher catalytic activity than Ce0.83Ti0.15Pt0.02O2- and Ce0.98Pt0.02O2-δ [4]. Further, experiments were conducted to determine the deactivation of these catalysts by performing the daily startup and shutdown of the reactor for over 24 hours. There was no sintering of Pt and no carbonate formation and, therefore, the catalyst did not deactivate even after prolonged reaction. There was no carbonate formation because of the highly acidic nature of Ce4+, Ti4+ ions in the catalysts. Further, PROX activity of these catalysts has been studied. Ce0.83Ti0.15Pt0.02O2- and Ce0.98Pt0.02O2-δ showed high activity, large operating temperature window and low working temperature proving them to be highly effective PROX catalysts.
In the 6th chapter we study the electrocatalysis of formic acid electro-oxidation and simultaneously mapping the electronic states of the electrodes by X-ray photoelectron spectroscopy (XPS). Ionically dispersed platinum in Ce1-xPtxO2-δ and Ce1-x-yTiyPtxO2-δ is very active towards oxygen evolution and formic acid oxidation. Higher electro-catalytic activity of Pt2+ ions in CeO2 and Ce1-xTixO2 compared to Pt0 in Pt/C is due to Pt2+ ion interaction with the supports, CeO2 and Ce1-xTixO2 respectively [5]. Further, ionic platinum does not suffer from CO poisoning effect unlike Pt0 in Pt/C. Utilization of lattice oxygen from the electrodes during the reaction has been demonstrated. This lattice oxygen exchange is responsible to convert CO to CO2 in the lower potential region to remove CO poisoning effect.
In 7th chapter we repeat our study on the noble metal ion reducible oxide interaction in Ce1-xPtxO2- and Ce1-xPdxO2- (x= 0.02) system by a novel electrochemical method combined with XPS. Working electrodes made of CeO2 and Ce0.98Pt0.02O2- mixed with 30% carbon are cycled between 0.0-1.2 V in potentio-static (chronoamperometry) and potentio-dynamic (cyclic voltametry) mode with reference to saturated calomel electrode (SCE). Reversible oxidation of Pt0 to Pt2+ and Pt4+ state due to the applied positive potential is coupled to simultaneous reversible reduction of Ce4+ to Ce3+ state. CeO2 reduces to CeO2-y (y= 0.35) after applying +1.2 V which is not reversible. But Ce0.98Pt0.02O2- reaches a steady state with Pt2+: Pt4+ in the ratio of 0.60: 0.40 and Ce4+: Ce3+ in the ratio of 0.55: 0.45 giving a composition Ce0.98Pt0.02O1.74 at 1.2 V which is reversible [6]. Composition of Pt ion substituted compound is reversible between Ce0.98Pt0.02O1.95 to Ce0.98Pt0.02O1.74 within the potential range of 0.0-1.2 V. Thus, Ce0.98Pt0.02O2- forms a stable electrode for oxidation of H2O to O2 unlike CeO2. A linear relation between oxidation of Pt2+ to Pt4+ with simultaneous reduction of Ce4+ to Ce3+ is observed demonstrating Pt-CeO2 metal support interaction is due to reversible Pt0/Pt2+/Pt4+ interaction with Ce4+/Ce3+ redox couple. Similar studies have been performed with Ce0.98Pd0.02O2- catalyst to show the redox coupling between Pd2+/Pd0 and Ce4+/Ce3+ redox couples. We expect similar redox coupling for Pd, Pt ions substituted TiO2, and Ce1-xTixO2.
In the final chapter 8, a critical review and conclusion on the results presented in the thesis is presented. The combustion synthesized catalysts reported in this thesis stabilizes the Pt and Pd metals in their ionic state rather than zero valent metallic state. Thus, the catalysts are uniform solid catalysts. High activity and stability of these catalysts are shown to be due to the electronic interaction between noble metal ions and the reducible oxide. Redox couples Pt0/Pt2+, Pt2+/Pt4+ and Pd0/Pd2+ interact with Ce4+/Ce3+, Ti4+/Ti3+ couples such that metal is oxidized and the support is reduced. This has been established in the thesis by a combined use of electrochemistry and XPS thus solving a long standing problem of metal support interaction in catalysis. We hope that the results presented in the thesis is a worthwhile contribution to catalysis.
(For mathematical equations pl refer pdf file.)
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