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Showing 561 to 570 of 594 (0.065 seconds)Spelling suggestions: "subject:"hydrogenation,"" "subject:"deydrogenation,""
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Self-adaptable catalysts : Importance of flexibility and applications in asymmetric catalysisFjellander, Ester January 2010 (has links)
The topic of this thesis is the design and synthesis of biaryl-based self adaptableligands for asymmetric metal catalysis. The results discussed in papers I-III are covered, together with some unpublished results concerning substrate-adaptable catalysts. A general survey of self-adaptable catalysts is presented first. The second chapter of this thesis starts with a survey of inversion barriers in biphenyl-based ligands and catalysts. Thereafter, the determination of barriers to conformational adaptation in dibenzoazepines and dibenzophosphepines is described. Palladium complexes with a diphosphine ligand or a diamine ligand, as well as the free diamine ligand, were studied. Entropies and enthalpies of activation were determined with variable temperature NMR spectroscopy. The mechanism of conformational change in the metal complexes was elucidated. The third chapter describes the synthesis of semiflexible and rigid phosphinite ligands, as well as their application in rhodium-catalysed asymmetric hydrogenation. Modest enantioselectivities (up to 63% ee) were obtained. The semiflexible ligand was found to behave like the most active rigid diastereomer. The fourth chapter describes the behaviour of amine and phosphoramidite ligands in model complexes relevant to the palladium-catalysed asymmetricallylic alkylation of benchmark substrates. Diphosphoramidite and aminephosphoramiditeligands were designed and synthesised. Pd(olefin) complexesof diamine and diphosphoramidite ligands were studied, and their symmetry determined. It was found that both types of ligands are able to adapt their conformation to the substrate. / QC20100630
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Flexibility – a tool for chirality control in asymmetric catalysisZalubovskis, Raivis January 2006 (has links)
This thesis deals with the design and synthesis of ligands for asymmetric catalysis: palladium catalyzed allylic alkylations, and rho-dium and iridium catalyzed hydrogenations of olefins. Chirally flexible phosphepine ligands based on biphenyl were synthesized and their properties were studied. The rotation barrier for configurationally flexible phosphepines was determined by NMR spectroscopy. The ratio of the atropisomers was shown to depend on the group bound to phosphorus. Only complexes with two homochiral ligands bound to the metal center were observed upon complexation with Rh(I). It was shown that one diastereomer of the flexible ligand exhibits higher activity but lower selectivity than its diastereomer in the rhodium catalyzed hydrogenation of methyl alfa-acetamidocinnamate. These ligands were also tested in nickel catalyzed silabora-tions. Chiral P,N-ligands with pseudo-C2 and pseudo-CS symmetry based on pyrrolidines-phospholanes or azepines-phosphepines were synthesized and studied in palladium catalyzed allylic alkylations. Semi-flexible azepine-phosphepine based ligands were prepared and their ability to adopt pseudo-C2 or pseudo-CS symmetry depending on the substrate in allylic alkylations was studied. It was shown on model allyl systems with flexible N,N-ligands that the ligand prefers CS-symmetry in compexes with anti-anti as well as syn-syn allyl moieties, but that for the latter type of complexes, according to computations, the configuration of the ligand is R*,R* in the olefin complexes formed after addition of a nucleophile to the allylic group. A preliminary investigation of the possibilities to use a su-pramolecular approach for the preparation of P,N-ligands with pseudo-C2 and pseudo-S symmetry was made. An N,N-ligand with C2 symmetry was prepared and its activity in palladium catalyzed ally-lic alkylation was studied. Pyridine-based P,N-ligands were tested in iridium catalyzed hy-drogenations of unfunctionalized olefins with good activities and se-lectivities. In order to attempt to improve the selectivity, ligands with a chirally flexible phosphepine fragment were prepared and applied in catalysis with promising results. / QC 20100929
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| 563 |
Metal nanoparticles stabilized by alkaloids in glycerol : from design to catalytic applications / Nanoparticules métalliques stabilisées par des alcaloïdes dans le glycérol : du design à l’application en catalyseReina Tapia, Antonio 03 October 2017 (has links)
Les nanoparticules métalliques (MNPs) ont un grand succès dans les dernières décennies dû à la variété d'applications dans différents domaines (microélectronique, matériaux, catalyse). Mis à part les solvants organiques, les liquides ioniques, l'eau, le CO2 supercritique et les polyols, en particulier le glycérol, ont démontré leur capacité à stabiliser et immobiliser les nanoparticules métalliques. Ces milieux évitent l'agglomération des MNPs et facilitent leur recyclage. Des nanoparticules de Pd(0) et Ni(0) dans le glycérol, sphériques, petites en taille et bien dispersées, ont été synthétisées avec succès à partir d'une méthodologie simple sous pression d'hydrogène, en présence de différents stabilisants (alkaloïdes, phosphine, polymer). La caractérisation complète de ces matériaux en solution et à l'état solide, ainsi que la possibilité de faire des synthèses à grande échelle et de stocker les solutions catalytiques longtemps, montrent la grande stabilité de ces solutions colloïdales. Les nanoparticules dans le glycérol ont été impliquées dans une large variété de transformations : hydrogénations, hydrodéhalogénations, couplages de Hiyama, additions conjuguées et hydrosilylations. De plus, nous avons étudié l'effet du stabilisant sur la réactivité catalytique, nous permettant de contrôler l'état de surface des nanoparticules et moduler ainsi leur réactivité. Nous avons montré, de même, la capacité du glycérol pour immobiliser les catalyseurs, ce qui s'est traduit par la possibilité de recycler la phase catalytique entre 4 et 10 fois sans perte de metal. En parallèle, nous avons évalué le comportement du Ni(OAc)2 libre de ligands dans le glycérol, en tant que catalyseur alternatif pour des couplages C-C et C-hétéroélément. Nous présentons aussi une étude en flux continu, en collaboration avec la Maison Européenne des Procédés Innovants (MEPI), pour l'hydrogénation de différents groupes fonctionnels, en utilisant les PdNPs dans le glycérol synthétisées préalablement. / Metal nanoparticles (MNPs) have been largely studied in the last decades due to their interesting properties which found applications in several fields (microelectronics, materials and catalysis, among others). In contrast to common organic solvents, ionic liquids, water, supercritical CO2, polyols such as glycerol, represent innovative solvents for the immobilization of MNPs, avoiding their agglomeration and facilitating their recycling. Small, spherical, and well-dispersed Pd(0) and Ni(0) nanoparticles were synthesized under hydrogen pressure in glycerol, in the presence of different kinds of stabilizers (cinchona-based alkaloids, phosphine, polymer). The high stability of these colloidal solutions permitted the full characterization both in solution and at solid state, large-scale synthesis, and stocking the solutions for months. These colloidal catalysts were applied in a large variety of transformations including hydrogenations, hydrodehalogenations, Hiyama C-C couplings, hydrosilylation reactions, and Michael conjugate additions. Furthermore, we conducted a comparative study exhibiting the differences in catalytic reactivity by effect of the stabilizer, allowing us tuning the surface-state of the nanoparticles. Moreover, we showed the ability of glycerol to immobilize metal nanoparticles permitting the recycle of the catalytic phase between 4 and 10 times, without metal leaching. Additionally, we studied the behavior of ligand-free Ni(OAc)2 in glycerol as an alternative catalyst for C-C and C-heteroatom couplings. Also, we developped a continuous flow study, in collaboration with the Maison Européenne des Procédés Innovants (MEPI), for the hydrogenation of different functional groups, using PdNPs in glycerol
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Nouvelles générations d'électrolyte pour batterie lithium polymère / News generations of electrolyte for lithium polymer batteryThiam, Amadou 21 July 2015 (has links)
Le but de cette thèse était de développer de nouveaux électrolytes polymères pour une application batteries lithium métal polymère. Le premier volet concerne le développement des réseaux semi-interpénétrés à base de POE et d'un polycondensat. Ces types d'électrolytes ont permis de d'améliorer les propriétés mécaniques et les conductivités à haute et basse température. L'ajout de NCC comme renfort sur ces réseaux semi-interpénétrés a permis d'atteindre propriétés physico-chimiques intéressantes et des durées de vie élevées. De plus l'hydrogénation du polycondensat permettant de moduler sont taux de réticulation a permis d'obtenir un électrolyte (en présence du LiTFSI) présentant des conductivités de 1S.cm-1 à 90°C pour un rapport O/Li=20 et O/Li=30 avec une tenue mécanique de 0,5MPa jusqu'à 100°C. Dans le second volet une série de sels de lithium à anion organique a été synthétisée et caractérisée. Ces sels de lithium présentent des bonnes stabilités électrochimiques, thermiques et des conductivités cationiques parfois plus élevées que LITFSI en milieu polymère. Le dernier volet concerne la synthèse et la caractérisation physico-chimique des nouveaux ionomères perfluoré. Ces nouveaux ionomères à conduction cationique unipolaire sont obtenus à partir de monomères aromatiques porteurs de fonctions ioniques ayant une forte aptitude à la dissociation et des nombres de transport cationique proche de 1 à 70°C. / The aim of this thesis was to develop new polymer electrolytes for application of lithium metal polymer batteries. The first part concerns the development of semi-interpenetrating networks based on POE and a polycondensat. These types of electrolytes made it possible to improve the mechanical properties and conductivity at high and low temperatures. The addition of NCC as a reinforcement on the semi-interpenetrating network has led to interesting physicochemical properties and high cycle life for batteries.The partial hydrogenation of the polycondensat allowing the modulation of the reticulation ratio has allow to elaborate as an electrolyte (in the presence of LiTFSI) exhibiting 1S.cm-1 conductivities at 90 ° C for a ratio O/Li=20 and O/Li=30 with a mechanical strength of 0.5MPa to 100 ° C. In the second part a range of lithium with organic anion was synthesized and characterized. These lithium salts show good electrochemical and thermal stability, whereas ionics conductivities are sometimes higher than LiTFSI in polymer medium. The last part concerns the synthesis and physicochemical characterization of new perfluorinated ionomers. These new cationic ionomers with a unipolar conduction are obtained from aromatic monomers carriers ionic functional having a high ability to dissociation and cation transport numbers close to 1 at 70 ° C.
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Propriedades estruturais e eletrônicas de nanotubos de carbono, BN e híbridos BxCyNz: um estudo por primeiros princípiosFreitas, Aliliane Almeida de 06 March 2015 (has links)
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Previous issue date: 2015-03-06 / Coordenação de Aperfeiçoamento de Pessoal de Nível Superior - CAPES / In the present work, we use first-principles calculations based on density functional theory, as
implemented in the SIESTA code, to investigate the changes in the structural and electronic properties
of the carbon, BN, and hybrid BxCyNz nanotubes produced by one or two of the following
mechanisms: doping with carbon atoms, the application of external electric fields, by flattening
of the cross section, the encapsulation of a carbon nanowire or the adsorption of hydrogen atoms
(hydrogenation).
We start with the study of double-walled boron nitride nanotubes (DWBNNTs), zig-zag and
armchair, doped with carbon atoms, with chiral vectors (8,0)@(16,0) and (5,5)@(10,10), respectively.
Two types of doping were considered: one C atom substituting a B atom on the inner
wall (IW) and one C atom substituting a N atom on the outer wall (OW), which we call of
CB[IW]@CN[OW], and the opposite situation results in CN[IW]@CB[OW]. In this sense, we generate
a (type-p semiconductor)@(type-n semiconductor) and a (type-n semiconductor)@(type-p semiconductor),
where the resulting DWBNNTs can be thought of as p-n junctions. At the same time,
we apply an external electric field, with magnitude of 0,3 V/Å, in different directions, namely,
perpendicular (Ey), parallel (Ex), and antiparallel (Ex) to the line formed by the dopants. Thus,
depending on the direction of the applied field, we observe an increase or decrease in the band
gap energy between the defect levels (Eig), and such cases are related to the reverse and direct
polarization of the p-n junction, respectively.
Afterwards, we study the insertion of a carbon nanowire (CNW) inside a (10.0) zigzag carbon
nanotube and inside a (10.0) zig-zag BN nanotube. Such systems were called CNW@SWCNT and
CNW@SWBNNT, respectively. We produce the flattening of the nanotubes and verify the behavior
of the atomic structure of the nanowire as the flattening of the nanotube increases. From the
obtained results, it was possible to conclude that, for both CNW@SWCNT and CNW@SWBNNT,
there is a critical distance dc (distance between the parallel planes of the flattened nanotubes (d)),
with the value of 3.60 Å, so that we can summarize our findings as follows: in the case d > dc,
the carbon nanowire does not undergo any deformation; and in the reverse case (d < dc), the carbon
nanowire binds to the wall of the nanotube and undergoes deformations. Regarding the electronic
properties, we verify that the encapsulation of the CNW inside the SWCNT and SWBNNT, produces
a significant reduction of the band gap energy (Eg) of such systems. Moreover, we observe
ABSTRACT viii
the creation of Dirac points for some flattening ratios of the nanotubes.
Finally, we carry out a study on the adsorption of hydrogen atoms (hydrogenation) on the surface
of double-walled boron nitride nanotubes (DWBNNTs) and hybrid nanotubes of boron nitride
and carbon (DW(BN)xCyNTs). Due to the fact that the nanotubes have two walls, we consider the
following cases: (i) coverages of 2H, 4H, 8H, 12H, and 16H on the inner wall, (ii) coverages of
2H, 4H, 8H, 16H, and 32H on the outer wall, and (iii) coverages of 2H, 4H, 8H, 16H, and 32H on
both walls. Curiously, we find that for all hydrogen coverages considered, a strong deformation
occurs in the hydrogen regions, causing the cross section of the nanotubes take different polygonal
shapes: ellipsoidal, rectangular, hexagonal or octahedral. For coverages of 16H and 32H only on
the outer wall, we observe that some hydrogens desorbed from the wall forming isolated H2 molecules
without preferential orientation. We verify that, in some cases, the bond angles between
the B, N and H or C and H atoms exhibit characteristics of the sp3 hybridization. Regarding the
structural stability, we verify that the adsorption of H atoms in DWBNCNTs is more favorable
than in DWBNNTs. Moreover, we conclude that is possible to control the band gap energy of the nanotubes through the hydrogen coverage. / No presente trabalho, usamos cálculos de primeiros princípios baseados na Teoria do Funcional
da Densidade, como implementado no código SIESTA, para investigarmos as alterações nas
propriedades estruturais e eletrônicas de nanotubos de carbono, de BN e híbridos BxCyNz, produzidas
por um ou dois dos seguintes mecanismos: dopagem com átomos de carbono, aplicação de
campos elétricos externos, pelo achatamento da secção transversal, encapsulamento de um nanofio
de carbono ou pela adsorção de átomos de hidrogênio (hidrogenação).
Iniciamos com o estudo de nanotubos de nitreto de boro de parede dupla (DWBNNTs), zig-zag
e armchair, dopados com átomos de carbono, com vetores quirais (8,0)@(16,0) e (5,5)@(10,10),
respectivamente. Duas situações de dopagem foram consideradas: um átomo de C substituindo um
átomo de B na parede interna (IW) e um átomo de C substituindo um átomo de N na parede externa
(OW) a qual chamamos de CB[IW]@CN[OW], e a situação oposta resulta em CN[IW]@CB[OW]. Neste
sentido, construímos um (semicondutor do tipo-p)@(semicondutor do tipo-n) e um (semicondutor
do tipo-n)@(semicondutor do tipo-p) onde os DWBNNTs resultantes podem ser pensados como
junções p-n. Paralelamente, aplicamos um campo elétrico externo, com magnitude de 0,3 V/Å, em
diferentes direções, a saber, perpendicular (Ey), paralelo (Ex) e anti-paralelo (Ex) a linha formada
pelos dopantes. Assim, dependendo da direção do campo aplicado, observamos um aumento ou
diminuição do gap de energia entre os níveis de defeitos (Eig) e tais casos estão relacionados a
polarização reversa e direta da junção p-n, respectivamente.
Em seguida, estudamos a inserção de um nanofio de carbono (CNW) no interior de um nanotubo
de carbono e de BN, ambos com vetor quiral (10.0). Tais sistemas foram chamados de
CNW@SWCNT e CNW@SWBNNT, respectivamente. Nós produzimos o achatamento dos nanotubos
e verificamos o comportamento da estrutura atômica do nanofio a medida que o achatamento
do nanotubo aumenta. A partir dos resultados obtidos, foi possível concluir que para ambos
os CNW@SWCNT e CNW@SWBNNT, existe uma distancia crítica dc (distância entre os planos
paralelos dos nanotubos achatados (d)), com um valor de 3.60 Å, de tal forma que nós podemos
resumir as nossas descobertas como: no caso de d > dc, o nanofio de carbono não sofre nenhuma
deformação; e no caso reverso (d < dc), o nanofio de carbono liga-se a parede do nanotubo e sofre
deformações. Em relação as propriedades eletrônicas, verificamos que o encapsulamento do CNW
nos SWCNT e SWBNNT, produz uma significativa redução do gap de energia (Eg) de tais sisteRESUMO
vi
mas. Além disso, observamos a formação de pontos de Dirac para algumas taxas de achatamento
dos nanotubos.
Por último, nós realizamos um estudo da adsorção de átomos de hidrogênio (hidrogenação)
sobre a superfície de um nanotubo de parede dupla de nitreto de boro (DWBNNTs) e um nanotubo
híbrido de nitreto de boro e carbono (DW(BN)xCyNTs). Devido ao fato dos nanotubos possuírem
duas paredes, consideramos os seguintes casos: (i) coberturas de 2H, 4H, 8H, 12H e 16H na parede
interna, (ii) coberturas de 2H, 4H, 8H, 16H e 32H na parede externa e (iii) coberturas de 2H, 4H,
8H, 16H e 32H em ambas as paredes. Curiosamente, verificamos que em todas as coberturas de
hidrogênio consideradas, uma forte deformação ocorre nos locais de hidrogênio, fazendo a secção
transversal dos nanotubos se transformar em diferentes formas poligonais: elipsoidal, retangular,
hexagonal ou octaedral. Para coberturas de 16H e 32H apenas na parede externa, observamos que
alguns hidrogênios se dessorveram da parede formando moléculas de H2 isoladas sem orientação
preferencial. Verificamos que em alguns casos, os ângulos de ligação entre os átomos de B, N e H
ou C e H exibem características da hibridação sp3. Com relação a estabilidade estrutural, verificamos
que a adsorção de átomos de H em DWBNCNTs é mais favorável do que em DWBNNTs.
Ademais, concluímos que é possível controlar o gap de energia dos nanotubos através da cobertura
de hidrogênio.
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Estudo da hidrogenação para pulverização de ligas à base de terras raras com Nb para eletrodos de hidreto metálico / Study of hydrogenation for pulverization of rare earth alloys with nb for metal hydride electrodesFERREIRA, ELINER A. 22 June 2016 (has links)
Submitted by Claudinei Pracidelli (cpracide@ipen.br) on 2016-06-22T13:51:24Z
No. of bitstreams: 0 / Made available in DSpace on 2016-06-22T13:51:24Z (GMT). No. of bitstreams: 0 / Tese (Doutorado em Tecnologia Nuclear) / IPEN/T / Instituto de Pesquisas Energeticas e Nucleares - IPEN-CNEN/SP
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Estudo da hidrogenação para pulverização de ligas à base de terras raras com Nb para eletrodos de hidreto metálico / Study of hydrogenation for pulverization of rare earth alloys with nb for metal hydride electrodesFERREIRA, ELINER A. 22 June 2016 (has links)
Submitted by Claudinei Pracidelli (cpracide@ipen.br) on 2016-06-22T13:51:24Z
No. of bitstreams: 0 / Made available in DSpace on 2016-06-22T13:51:24Z (GMT). No. of bitstreams: 0 / Neste trabalho foram estudadas as series de ligas La0,7Mg0,3Al0,3Mn0,4Co(0,5-x)NbxNi3,8 (x =0 a 0,5) e La0,7Mg0,3Al0,3Mn0,4Nb(0,5-x)Ni(3,8-x) (x =0,3; 0,5 e 1,3), como eletrodo negativo de baterias de Níquel Hidreto Metálico. A pulverização das ligas foi realizada com duas pressões de H2 (2 bar e 9 bar). A capacidade de descarga das baterias de níquel hidreto metálico foi analisada pelo equipamento de testes elétricos Arbin BT-4. As ligas, no estado bruto de fusão, foram analisadas por microscopia eletrônica de varredura (MEV), espectroscopia de energia dispersiva (EDS) e difração de raios-X. Com o aumento da concentração de nióbio nas ligas nota-se a diminuição da estabilidade cíclica das baterias e da capacidade máxima de descarga. A capacidade de descarga máxima obtida foi para a liga La0,7Mg0,3Al0,3Mn0,4Co0,5Ni3,8 (45,36 mAh) e a bateria que apresentou a melhor performance foi a liga La0,7Mg0,3Al0,3Mn0,4Co0,4Nb0,1Ni3,8 (44,94 mAh). / Tese (Doutorado em Tecnologia Nuclear) / IPEN/T / Instituto de Pesquisas Energeticas e Nucleares - IPEN-CNEN/SP
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Processus non-linéaires au cours de l'hydrogénation du NO2 sur catalyseurs à base de platine et de rhodiumBarroo, Cédric 11 September 2014 (has links)
Le travail de thèse propose d’éclaircir les dynamiques qui régissent les réactions d’hydrogénation du dioxyde d’azote (NO2) se déroulant à la surface de catalyseurs modèles de platine, de rhodium et de leur alliage Pt-Rh. Une meilleure compréhension de la réaction catalytique en conditions réactionnelles permettrait, à terme, un meilleur contrôle de la réaction. De manière similaire, le comportement du catalyseur permettrait d’orienter la synthèse de catalyseurs afin d’en augmenter la sélectivité et/ou activité. La structure de ces catalyseurs ainsi que l’analyse des processus sont effectuées à l’échelle nanométrique grâce à l’utilisation de microscopies à effet de champ :la microscopie ionique à effet de champ (FIM) et la microscopie d’émission d’électrons par effet de champ (FEM). La réaction NO2+H2 étudiée à 390 K sur le platine permet de mettre en évidence la présence de différents domaines réactionnels :dynamique monostable, oscillations périodiques auto-entretenues, oscillations périodiques bimodales, ainsi que des oscillations bruitées. Malgré la présence importante de fluctuations à l’échelle du nanomètre, les traitements de signaux mettent en évidence une importante robustesse qui se traduit par un temps de corrélation qui s’étend sur plusieurs centaines de périodes. Les données donnent matière à la reconstruction de l’attracteur dynamique consistant en un cycle limite. La pression d’hydrogène est le paramètre de contrôle qui est varié de sorte à provoquer l’apparition d’oscillations selon une bifurcation de type homocline dans ce cas-ci. Des mesures à haute-vitesse d’acquisition démontrent que l’ignition des différentes faces réactives s’effectue de manière désynchronisée, et la vitesse de propagation est de l’ordre de ~2 μm/s. Au sein d’une seule face, à l’échelle du nanomètre, des propagations de fronts d’ondes chimiques peuvent également être observées à une vitesse de ~2 μm/s, en accord avec les vitesses analysées lors d’expériences menées à l’échelle du micromètre et du millimètre. Sur base des observations, un mécanisme réactionnel de production d’H2O a été proposé. La réaction sur le rhodium à 450 K engendre également des oscillations périodiques qui diffèrent par une robustesse plus faible et par l’apparition d’un cycle limite selon une bifurcation de Hopf. Des mesures exploratoires à 500 K font ressortir la présence de chaos dans le système. Finalement, l’alliage Pt-Rh utilisé comme catalyseur permet d’obtenir des oscillations à 425 K de période comprise entre celles observées sur les deux métaux purs. L’ensemble des expériences et des résultats obtenus à l’échelle du nanomètre permet pour la première fois de valider la théorie des systèmes dynamiques à une telle échelle. / Doctorat en Sciences / info:eu-repo/semantics/nonPublished
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Kinetic and mechanistic studies of CO hydrogenation over cobalt-based catalystsSchweicher, Julien 25 November 2010 (has links)
During this PhD thesis, cobalt (Co) catalysts have been prepared, characterized and studied in the carbon monoxide hydrogenation (CO+H2) reaction (also known as “Fischer-Tropsch” (FT) reaction). In industry, the FT synthesis aims at producing long chain hydrocarbons such as gasoline or diesel fuels. The interest is that the reactants (CO and H2) are obtained from other carbonaceous sources than crude oil: natural gas, coal, biomass or even petroleum residues. As it is well known that the worldwide crude oil reserves will be depleted in a few decades, the FT reaction represents an attractive alternative for the production of various fuels. Moreover, this reaction can also be used to produce high value specialty chemicals (long chain alcohols, light olefins…).<p>Two different types of catalysts have been investigated during this thesis: cobalt with magnesia used as support or dispersant (Co/MgO) and cobalt with silica used as support (Co/SiO2). Each catalyst from the first class is prepared by precipitation of a mixed Co/Mg oxalate in acetone. This coprecipitation is followed by a thermal decomposition under reductive atmosphere leading to a mixed Co/MgO catalyst. On the other hand, Co/SiO2 catalysts are prepared by impregnation of a commercial silica support with a chloroform solution containing Co nanoparticles. This impregnation is then followed by a thermal activation under reductive atmosphere.<p>The mixed Co/Mg oxalates and the resulting Co/MgO catalysts have been extensively characterized in order to gain a better understanding of the composition, the structure and the morphology of these materials: thermal treatments under reductive and inert atmospheres (followed by MS, DRIFTS, TGA and DTA), BET surface area measurements, XRD and electron microscopy studies have been performed. Moreover, an original in situ technique for measuring the H2 chemisorption surface area of catalysts has been developed and used over our catalysts.<p>The performances of the Co/MgO and Co/SiO2 catalysts have then been evaluated in the CO+H2 reaction at atmospheric pressure. Chemical Transient Kinetics (CTK) experiments have been carried out in order to obtain information about the reaction kinetics and mechanism and the nature of the catalyst active surface under reaction conditions. The influence of several experimental parameters (temperature, H2 and CO partial pressures, total volumetric flow rate) and the effect of passivation are also discussed with regard to the catalyst behavior.<p>Our results indicate that the FT active surface of Co/MgO 10/1 (molar ratio) is entirely covered by carbon, oxygen and hydrogen atoms, most probably associated as surface complexes (possibly formate species). Thus, this active surface does not present the properties of a metallic Co surface (this has been proved by performing original experiments consisting in switching from the CO+H2 reaction to the propane hydrogenolysis reaction (C3H8+H2) which is sensitive to the metallic nature of the catalyst). CTK experiments have also shown that gaseous CO is the monomer responsible for chain lengthening in the FT reaction (and not any CHx surface intermediates as commonly believed). Moreover, CO chemisorption has been found to be irreversible under reaction conditions.<p>The CTK results obtained over Co/SiO2 are quite different and do not permit to draw sharp conclusions concerning the FT reaction mechanism. More detailed studies would have to be carried out over these samples.<p>Finally, Co/MgO catalysts have also been studied on a combined DRIFTS/MS experimental set-up in Belfast. CTK and Steady-State Isotopic Transient Kinetic Analysis (SSITKA) experiments have been carried out. While formate and methylene (CH2) groups have been detected by DRIFTS during the FT reaction, the results indicate that these species play no role as active intermediates. These formates are most probably located on MgO or at the Co/MgO interface, while methylene groups stand for skeleton CH2 in either hydrocarbon or carboxylate. Unfortunately, formate/methylene species have not been detected by DRIFTS over pure Co catalyst without MgO, because of the full signal absorption.<p> / Doctorat en Sciences de l'ingénieur / info:eu-repo/semantics/nonPublished
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Vibrational properties of epitaxial silicene on Ag(111) / Die Schwingungseigenschaften von epitaktischen Silicen auf Ag(111)Solonenko, Dmytro Ihorovych 18 December 2017 (has links) (PDF)
This dissertation works out the vibrational properties of epitaxial silicene, which was discovered by Vogt et al. in 2012 by the epitaxial synthesis on the silver substrate. Its two-dimensional (2D) character is modified in comparison to the free-standing silicene due to its epitaxial nature, since the underlying substrate alters the physical properties of silicene as a result of the strong hybridization of the electronic levels of the substrate and adlayer. The growth of silicene layers is complicated by the sensitivity of the Si structures to the experimental conditions, mainly temperature, resulting in the formation of several seemingly different surface reconstructions. Another Si structure appears on the Ag surface at a supramonolayer coverage. The Raman spectroscopy was utilized to understand the relation between different Si structures and reveal their origin as well as to investigate the phonon-related physical properties of two-dimensional Si sheets.
The central core of this work is the growth and characterization of these 2D silicene monolayers on the Ag (111) surface as well as the formation of silicene multilayer structures. The characterization of these materials was performed using in situ surface-sensitive measurement methods such as Raman spectroscopy and low-energy electron diffraction under ultra-high vacuum conditions due to high chemical reactivity of epitaxial silicene. Additional characterization was done ex situ by means of scanning force microscopy. The experimentally determined spectral signature of the prototypical epitaxial (3x3)/(4x4) silicene structure was confirmed by ab initio calculations, in collaboration with theory groups. The Raman signatures of the other 2D and 3D Si phases on Ag (111) were determined which allowed us to provide a clear picture of their formation depending on the preparation conditions.
The monitoring of the silicene multi-layer growth yielded the vibrational signature of the top layer, reconstructed in a (√3x√3) fashion. It was compared to the inverse, (√3x√3)-Ag/Si(111), system showing the vast amount of similarities, which suggest that the (√3x√3) reconstruction belong to the silver layer. The chemical and physical properties of this surface structure additionally strengthen this equivalence.
The possibility of functionalization of epitaxial silicene was demonstrated via exposure to the atomic hydrogen under UHV conditions. The adsorbed hydrogen covalently bonds to the silicene lattice modifying it and reducing its symmetry. As shown by Raman spectroscopy, such modification can be reversed by thermal desorption of hydrogen. The excitation-dependent Raman measurements also suggest the change of the electronic properties of epitaxial silicene upon hydrogenation suggesting that its originally semi-metallic character is modified into a semiconducting one. / Die experimentellen Forschungsarbeiten zum Thema Silicen basieren auf den 2012 von Vogt et al. durchgeführten Untersuchungen zu dessen Synthese auf Silbersubstraten. Diese Untersuchungen lieferten die Grundlage, auf der zweidimensionales (2D) epitaktisches Silicen sowie weitere 2D Materialien untersucht werden konnten. In den anfänglichen Arbeiten konnte dabei gezeigt werden, dass sich die Eigenschaften von epitaktischem Silicen gegenüber den theoretischen Vorhersagen von frei-stehendem Silicen unterscheiden. Darüber hinaus verkomplizieren sich die experimentellen Untersuchungen dieses 2D Materials, da auf dem Ag(111) Wachstumssubstrat sechs verschiedene 2D Si Polytypen existieren. Eine detaillierte Darstellung dieser Untersuchungen findet sich in dem einführenden Kapitel der vorliegen Promotionsschrift. Der zentrale Kern dieser Arbeit beschäftigt sich mit dem Wachstum und der Charakterisierung dieser 2D Silicen Monolagen auf Ag(111) Oberflächen sowie der Bildung von Silicen- Multilagen Strukturen. Die Charakterisierung dieser Materialien wurde in situ mit oberflächenempfindlichen Messmethoden wie der Raman Spektroskopie und der niederenergetischen Elektronenbeugung unter Ultrahochvakuum-Bedingungen durchgeführt. Eine zusätzliche Charakterisierung erfolgte ex situ mittels Raster-KraftMikroskopie. Die experimentell bestimmte spektrale Raman-Signatur der prototypischen epitaktischen (3x3)/(4x4) Silicene Struktur wurde durch ab initio Rechnungen, in Zusammenarbeit mit Theoriegruppen, bestätigt. Durch diesen Vergleich wir die zweidimensionale Natur der epitaktischen Silicen-Schichten vollständig bestätigt, wodurch andere mögliche Interpretationen ausgeschlossen werden können. Darüber hinaus wurden die Ramans-Signaturen der weiteren 2D und 3D Siliziumphasen auf Ag(111) bestimmt, wodurch sich ein klares Bild der Bildung dieser Strukturen in Abhängigkeit von den Präparationsbedingungen ergibt. Um die Möglichkeit der Funktionalisierung von Silicen und der weiteren 2D Si Strukturen zu testen, wurden diese unter UHV Bedingungen atomarem Wasserstoff ausgesetzt. Durch die Bindung zu den Wasserstoffamen wird die kristalline Struktur der Silicen-Schichten modifiziert und die Symmetrie reduziert, was sich deutlich in der spektralen Raman-Signatur zeigt. Wie mittels Raman Spektroskopie gezeigt werden konnte, kann diese Modifikation durch thermische Desorption des Wasserstoffs rückgängig gemacht werden, ist also reversibel. Raman Messungen mit verschiedenen Anregungswellenlängen deuten darüber hinaus auf die Änderung der elektronischen Eigenschaften der Silicen-Schichten durch die Hydrierung hin. Der ursprüngliche halbmetallische Charakter der epitaktischen Silicen-Schicht geht möglicherweise in einen halbleitenden Zustand über. Das Wachstum von Silicen Multilagen wurde ebenfalls mit in situ Ramanspektroskopie verfolgt. Die sich dabei ergebene Raman-Signatur wurde mit der Raman-Signatur von Ag terminiertem Si(111) verglichen. Hier zeigen sich große Ähnlichkeiten, die auf eine ähnliche atomare Struktur hindeuten und zeigen, dass Ag Atome für die Ausbildung der Oberflächenstruktur während des Wachstums der Si-Lagen verantwortlich sind. Die chemischen und physikalischen Eigenschaften dieser Struktur bestärken zusätzlich diese Äquivalenz.
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