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Development of Nanostructured Ceramic Catalysts Based on Mixed Metal OxidesGonçalves, Alexandre Amormino Dos Santos 28 November 2018 (has links)
No description available.
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DEVELOPMENT OF ADVANCED ENERGY ABSORPTION SYSTEM USING NANOPOROUS MATERIALSSurani, Falgun January 2006 (has links)
No description available.
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Modeling the Self-Assembly of Ordered Nanoporous MaterialsJin, Lin 01 September 2012 (has links)
Porous materials have long been a research interest due to their practical importance in traditional chemical industries such as catalysis and separation processes. The successful synthesis of porous materials requires further understanding of the fundamental physics that govern the formation of these materials. In this thesis, we apply molecular modeling methods and develop novel models to study the formation mechanism of ordered porous materials. The improved understanding provides an opportunity to rational control pore size, pore shape, surface reactivity and may lead to new design of tailor-made materials. To attain detailed structural evolution of silicate materials, an atomistic model with explicitly representation of silicon and oxygen atoms is developed. Our model is based on rigid tetrahedra (representing SiO4) occupying the sites of a body centered cubic (bcc) lattice. The model serves as the base model to study the formation of silica materials. We first carried out Monte Carlo simulations to describe the polymerization process of silica without template molecules starting from a solution of silicic acid in water at pH 2. We predicted Qn evolutions during silica polymerization and good agreement was found compared with experimental data, where Qn is the fraction of Si atoms with n bridging oxygens. The model captures the basic kinetics of silica polymerization and provides structural evolution information. Next we generalize the application of this atomic lattice model to materials with tetrahedral (T) and bridging (B) atoms and apply parallel tempering Monte Carlo methods to search for ground states. We show that the atomic lattice model can be applied to silica and related materials with a rich variety of structures including known chalcogenides, zeolite analogs, and layered materials. We find that whereas canonical Monte Carlo simulations of the model consistently produce the amorphous solids studied in our previous work, parallel tempering Monte Carlo gives rise to ordered nanoporous solids. The utility of parallel tempering highlights the existence of barriers between amorphous and crystalline phases of our model. The role of template molecules during synthesis of ordered mesoporous materials was investigated. Implemented surfactant lattice model of Larson, together with atomic tetrahedral model for silica, we successfully modeled the formation of surfactant-templated mesoporous silica (MCM-41), with explicit representation of silicic acid condensation and surfactant self-assembly. Lamellar and hexagonal mesophases form spontaneously at different synthesis conditions, consistent with published experimental observations. Under conditions where silica polymerization is negligible, reversible transformation between hexagonal and lamellar phases were observed by changing synthesis temperatures. Upon long-time simulation that allows condensation of silanol groups, the inorganic phases of mesoporous structures were found with thicker walls that are amorphous and lack of crystallinity. Compared with bulk amorphous silica, the wall-domain of mesoporous silicas are less ordered withlarger fractions of three- and four-membered rings and wider ring-size distributions. It is the first molecular simulation study of explicit representations of both silicic acid condensation and surfactant self-assembly.
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Assessing one-dimensional diffusion in nanoporous materials from transient concentration profilesHeinke, Lars, Kärger, Jörg 25 July 2022 (has links)
The use of interference microscopy has enabled the direct
observation of transient concentration profiles generated by intracrystalline
transport diffusion in nanoporous materials. The thus accessible intracrystalline
concentration profiles contain a wealth of information which cannot be deduced
by any macroscopic method. In this paper, we illustrate five different ways for
determining the concentration-dependent diffusivity in one-dimensional systems
and two for the surface permeability. These methods are discussed by application
to concentration profiles evolving during the uptake of methanol by the zeolite
ferrierite and of methanol by the metal organic framework (MOF) manganese(II)
formate. We show that the diffusivity can be calculated most precisely by means
of Fick’s 1st law. As the circumstances permit, Boltzmann’s integration method
also yields very precise results. Furthermore, we present a simple procedure that
enables the estimation of the influence of the surface barrier on the overall
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Computational Studies of Membranes for Ethanol/water Separation and Carbon CaptureZou, Changlong 19 September 2022 (has links)
No description available.
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Global challenges of capturing carbon dioxideBrandani, Stefano, Mangano, Enzo 30 January 2020 (has links)
Within this general context, this talk will consider the use of novel nanoporous materials as the basis for
adsorption based separations [3] that will range from concentrated mixtures to direct capture of carbon
dioxide from air. An overview of different classes of materials will show how these can be tailored to
such a wide range of conditions. The sheer scale of the task leads to having to optimize systems and
speed up processes, which in turn brings in diffusion limitations.
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Self-organized nanoporous materials for chemical separations and chemical sensingPandey, Bipin January 1900 (has links)
Doctor of Philosophy / Department of Chemistry / Takashi Ito / Self-organized nanoporous materials have drawn a lot of attention because the uniform, highly dense, and ordered cylindrical nanopores in these materials provide a unique platform for chemical separations and chemical sensing applications. Here, we explore self-organized nanopores of PS-b-PMMA diblock copolymer thin films and anodic gallium oxide for chemical separations and sensing applications.
In the first study, cyclic voltammograms of cytochrome c on recessed nanodisk-array electrodes (RNEs) based on nanoporous films (11, 14 or 24 nm in average pore diameter; 30 nm thick) derived from polystyrene-poly(methylmethacrylate) diblock copolymers were measured. The faradic current of cytochrome c was observed on RNEs, indicating the penetration of cytochrome c (hydrodynamic diameter ≈ 4 nm) through the nanopores to the underlying electrodes. Compared to the 24-nm pores, the diffusion of cytochrome c molecules through the 11- and 14-nm pores suffered significantly larger hindrance. The results reported in this study will provide guidance in designing RNEs for size-based chemical sensing and also for controlled immobilization of biomolecules within nanoporous media for biosensors and bioreactors.
In another study, conditions for the formation of self-organized nanopores of a metal oxide film were investigated. Self-organized nanopores aligned perpendicular to the film surface were obtained upon anodization of gallium films in ice-cooled 4 and 6 M aqueous H2SO4 at 10 V and 15 V. The average pore diameter was in the range of 18 ~ 40 nm, and the anodic gallium oxide was ca. 2 µm thick. In addition, anodic formation of self-organized nanopores was demonstrated for a solid gallium monolith incorporated at the end of a glass capillary. Nanoporous anodic oxide monoliths formed from a fusible metal will lead to future development of unique devices for chemical sensing and catalysis.
In the final study, surface chemical property of self-organized nanoporous anodic gallium oxide is explored through potentiometric measurements. The nanoporous anodic and barrier layer gallium oxide structures showed slow potentiometric response only at acidic pH (≤ 4), in contrast to metallic gallium substrates that exhibited a positive potentiometric response to H⁺ over the pH range examined (3-10). The potentiometric response at acidic pH probably reflects some chemical processes between gallium oxide and HCl.
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Modélisation du comportement élastique des matériaux nanoporeux : application au combustible UO2 / Modeling of the elastic behavior of nanoporous materials : application to UO2 fuelHaller, Xavier 23 October 2015 (has links)
Le dioxyde d'uranium irradié (UO2), combustible nucléaire des réacteurs à eau pressurisée, contient deux populations de cavités saturées par des gaz de fission : i. des cavités intergranulaires plutôt lenticulaires, dont la taille varie de quelques dizaines à plusieurs centaines de nanomètres, ii. des cavités intragranulaires plutôt sphériques, dont la taille est de l'ordre du nanomètre. Des travaux récents ont montré qu'il existe un effet de surface à l'échelle des cavités nanométriques qui modifie le comportement élastique effectif du combustible. Ce travail vise à proposer un modèle micromécanique analytique capable de tenir compte de cette microstructure hétérogène ainsi que de l'effet de surface afin de décrire le comportement élastique macroscopique de l'UO2 irradié. La démarche mise en oeuvre est fondée sur une modélisation multi-échelles et s'appuie sur des techniques d'homogénéisation en mécanique des matériaux. L'UO2 irradié est décrit comme un matériau poreux contenant des nanocavités sphériques (cavités intragranulaires) et sphéroïdales (cavités intergranulaires), sous pression et orientées aléatoirement. L'effet de surface présent à l'échelle nanométrique est pris en compte via un modèle d'interface imparfaite cohérente entre la matrice et les cavités. Un modèle original fondé sur l'approche par motifs morphologiques représentatifs a été développé afin de décrire le comportement élastique effectif de ce milieu hétérogène. Le modèle analytique proposé repose sur des hypothèses simplificatrices dont la pertinence est évaluée à partir de simulations numériques par éléments finis qui s'appuient sur une formulation spécifique afin de tenir compte de la présence d'interfaces imparfaites cohérentes. / The irradiated uranium dioxide (UO2), which is the nuclear fuel of pressurized water reactors, contains two populations of cavities saturated by fission gaz: i. intergranular cavities almost lenticular in shape whose size ranges between few tens to several hundred nanometers, ii. intragranular cavities, almost spherical in shape whose size is of the order of the nanometer. Recent studies have shown the existence of a surface effect at the scale of nanometric cavities, which influences the effective elastic behavior of the nuclear fuel. In this work, an analytical micromechanical model, which is able to take into account this heterogeneous microstructure and the surface effect at the nanometric scale, is proposed to describe the macroscopic behavior of the irradiated UO2. The approach is based on a multiscale modeling and homogenization techniques in mechanics of materials. The irradiated UO2 is described as a porous media, which contains pressurized spherical nanocavities (intragranular cavities) and randomly oriented pressurized spheroidal cavities (intergranular cavities). The surface effect is taken into account with imperfect coherent interfaces between the matrix and the cavities. A novel model based on the morphologically representative pattern approach has been developed to describe the effective elastic behavior of this heterogeneous medium. The proposed model relies on assumptions whose relevance is evaluated with finite element simulations which require a specific formulation to take into account the imperfect coherent interfaces.
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Synthèse, structure et propriétés de polycyanurates réticulés et de matériaux nanoporeux générés en utilisant des liquides ioniques / Synthesis, structure and properties of crosslinked polycyanurates and nanoporous materials generated by using ionic liquidsVashchuk, Alina 16 January 2019 (has links)
Cette thèse de doctorat aborde de nouvelles conceptions de films à base de résines d’ester de cyanate (CER) en présence de liquides ioniques (LIs) en tant qu'agents multifonctionnels : catalyseurs, agents de modification réactifs, renforts ou agents porogènes. Les liquides ioniques de structures et de concentrations variables accélèrent de manière significative la polycyclotrimérisation du dicyanate d’ester de bisphenol E, en l'absence de tout solvant organique supplémentaire ou additif. Les réseaux de polycyanurates resultants dopés avec des liquides ioniques aprotiques peuvent constituer des matériaux prometteurs pour la production de structures photosensibles. De tels systèmes nanocomposites permettent la séparation, larécupération et le recyclage aisés des LIs par simple extraction, ce qui permet finalement l'obtention de films nanoporeux thermostables. Les caractéristiques de la porosité de ces matériaux dépendent de la concentration des LIs dans les précurseurs CERs. Les LIs protoniques contenant des groupements fonctionnels >NH et -OH, indépendamment de leurmasse molaire, de la structure chimique du cation et de l'anion, sont incorporés chimiquement dans le réseau polycyanurate. Ainsi, les matériaux hybrides obtenus avec des fragments de liquides ioniques pourraient fournir d’excellents candidats pour des recherches futures sur les ionomères et les nanocomposites. / This PhD thesis addresses new designs of cyanate ester resin (CER) films in the presence of ionic liquids as multifunctional agents: catalysts, reactive modifiers, fillers or porogens. It should be emphasized that ionic liquids (ILs) of varying structures and concentrations significantly accelerate the polycyclotrimerization of dicyanate ester of bisphenol E, in the absence of any additional organic solvent or additive. The resulting polycyanurate networks doped with aprotic ionic liquids can be promising materials for producing photosensitive structures. Such nanocomposite systems allow for easier separation, recovery, and recycling of ILs by mere extraction, which eventually affords thermally stable nanoporous films. The porosity features of these materials depend on the concentration of ILs in the CER precursors.Protic ILs containing functional >NH and -OH groups, regardless of molar mass, chemical structure of cation and anion, chemically incorporate into the polycyanurate network, thus the resulting hybrid materials with fragments of ionic liquids could provide excellent candidates for future research in ionomers and nanocomposites.
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Nanoporous layered oxide materials and membranes for gas separationsKim, Wun-Gwi 02 April 2013 (has links)
The overall focus of this thesis is on the development and understanding of
nanoporous layered silicates and membranes, particularly for potential applications in gas
separations. Nanoporous layered materials are a rapidly growing area of interest, and
include materials such as layered zeolites, porous layered oxides, layered
aluminophosphates, and porous graphenes. They possess unique transport properties that
may be advantageous for membrane and thin film applications. These materials also have
very different chemistry from 3-D porous materials due to the existence of a large,
chemically active, external surface area. This feature also necessitates the development of
innovative strategies to process these materials into membranes and thin films with high
performance.
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