Formation et propriétés des cristaux colloïdaux issus de l’auto-assemblage de microsphères de polymère

Bazin, Gwénaëlle

04 1900

Le besoin pour des biocapteurs à haute sensibilité mais simples à préparer et à utiliser est en constante augmentation, notamment dans le domaine biomédical. Les cristaux colloïdaux formés par des microsphères de polymère ont déjà prouvé leur fort potentiel en tant que biocapteurs grâce à l’association des propriétés des polymères et à la diffraction de la lumière visible de la structure périodique. Toutefois, une meilleure compréhension du comportement de ces structures est primordiale avant de pouvoir développer des capteurs efficaces et polyvalents. Ce travail propose d’étudier la formation et les propriétés des cristaux colloïdaux résultant de l’auto-assemblage de microsphères de polymère en milieu aqueux. Dans ce but, des particules avec différentes caractéristiques ont été synthétisées et caractérisées afin de corréler les propriétés des particules et le comportement de la structure cristalline. Dans un premier temps, des microsphères réticulées de polystyrène anioniques et cationiques ont été préparées par polymérisation en émulsion sans tensioactif. En variant la quantité de comonomère chargé, le chlorure de vinylbenzyltriméthylammonium ou le sulfonate styrène de sodium, des particules de différentes tailles, formes, polydispersités et charges surfaciques ont été obtenues. En effet, une augmentation de la quantité du comonomère ionique permet de stabiliser de façon électrostatique une plus grande surface et de diminuer ainsi la taille des particules. Cependant, au-dessus d’une certaine concentration, la polymérisation du comonomère en solution devient non négligeable, provoquant un élargissement de la distribution de taille. Quand la polydispersité est faible, ces microsphères chargées, même celles non parfaitement sphériques, peuvent s’auto-assembler et former des cristaux colloïdaux diffractant la lumière visible. Il semble que les répulsions électrostatiques créées par les charges surfaciques favorisent la formation de la structure périodique sur un grand domaine de concentrations et améliorent leur stabilité en présence de sel. Dans un deuxième temps, le besoin d’un constituant stimulable nous a orientés vers les structures cœur-écorce. Ces microsphères, synthétisées en deux étapes par polymérisation en émulsion sans tensioactif, sont formées d’un cœur de polystyrène et d’une écorce d’hydrogel. Différents hydrogels ont été utilisés afin d’obtenir des propriétés différentes : le poly(acide acrylique) pour sa sensibilité au pH, le poly(N-isopropylacrylamide) pour sa thermosensibilité, et, enfin, le copolymère poly(N-isopropylacrylamide-co-acide acrylique) donnant une double sensibilité. Ces microsphères forment des cristaux colloïdaux diffractant la lumière visible à partir d’une certaine concentration critique et pour un large domaine de concentrations. D’après les changements observés dans les spectres de diffraction, les stimuli ont un impact sur la structure cristalline mais l’amplitude de cet effet varie avec la concentration. Ce comportement semble être le résultat des changements induits par la transition de phase volumique sur les interactions entre particules plutôt qu’une conséquence du changement de taille. Les interactions attractives de van der Waals et les répulsions stériques sont clairement affectées par la transition de phase volumique de l’écorce de poly(N-isopropylacrylamide). Dans le cas des microsphères sensibles au pH, les interactions électrostatiques sont aussi à considérer. L’effet de la concentration peut alors être mis en relation avec la portée de ces interactions. Finalement, dans l’objectif futur de développer des biocapteurs de glucose, les microsphères cœur-écorce ont été fonctionnalisées avec l’acide 3-aminophénylboronique afin de les rendre sensibles au glucose. Les effets de la fonctionnalisation et de la complexation avec le glucose sur les particules et leur empilement périodique ont été examinés. La structure cristalline est visiblement affectée par la présence de glucose, même si le mécanisme impliqué reste à élucider. / The need for biosensors with high sensibility but simple preparation and use has been increasing, especially in the biomedical field. Crystalline colloidal arrays (CCAs) formed by polymer microspheres have already demonstrated great potential for biosensing applications, combining the polymer properties to the visible light diffraction caused by their periodic structure. However, a better understanding of the behavior of such structures is essential in the objective to develop efficient and versatile biosensors. This work proposes to investigate the formation and properties of CCAs created by the self-assembly of polymer microspheres in aqueous medium. For that purpose, particles with different features have been synthesized and studied to highlight the correlation between the properties of the particles and the behavior of the CCAs. First, anionic and cationic cross-linked polystyrene microspheres have been prepared by surfactant-free emulsion polymerization. Different sizes, shapes, polydispersities and surface charge densities have been obtained by the use of various amounts of charged comonomers, either vinylbenzyltrimethylammonium chloride or sodium styrenesulfonate. Indeed, an increasing amount of the ionic comonomer leads to a decreasing particle size because of the ability to electrostatically stabilize more surfaces. However, above a certain concentration, the polymerization of the comonomer in solution increases the polydispersity of the particle size. When allowed by a low polydispersity, the charged microspheres can self-assemble into CCAs with intense visible light diffraction, even for particles not quite spherical. It appears that the electrostatic repulsions created by the charges help in the formation of the periodic structure over a wide range of particle concentrations and improve their stability towards ionic strength. Secondly, the need for a sensitive component brought us to investigate core-shell structures. These microspheres, synthesized by a two-step surfactant-free emulsion polymerization, are made of a polystyrene core and a hydrogel shell. Different hydrogels have been used to achieve different properties: poly(acrylic acid) for pH-sensitivity, poly(N-isopropylacrylamide) for thermosensitivity and poly(N-isopropylacrylamide-co-acrylic acid) for double sensitivity to both stimuli. Above a certain critical concentration, and over a wide range of concentrations, these microspheres also form CCAs with visible light diffraction. The resulting crystalline structures also display a response to the stimuli, visible through changes in the diffraction spectra, but the response appears to be dependent on the microsphere concentration. This behavior seems to be the result of a change in the interactions between particles rather than the outcome of the volume change of the particles. Attractive van der Waals and repulsive steric interactions are clearly affected by the temperature-induced volume phase transition of poly(N-isopropylacrylamide) microspheres. In the case of pH-sensitive, electrostatic interactions are also to be considered. The effect of concentration can then related to the range of the interactions. Finally, in the objective to develop glucose sensors, the previous microspheres have been functionalized with 3-aminophenylboronic acid to make them responsive to glucose. The effects of the functionalization and complexation with glucose on the particles and their CCAs have been investigated. The crystalline structure is clearly affected by the presence of glucose, even though the mechanism involved remains to be clarified.

Surfactant-free emulsion polymerization

Microsphères de polymère

Polymer microspheres

Particules coeur-écorce

Core-shell particles

Thermosensibilité

Thermosensitivity

Sensibilité au pH

pH-sensitivity

Cristaux colloïdaux

Crystalline colloidal arrays

Biocapteurs de glucose

Glucose biosensors

Towards the nanomechanical actuation and controlled assembly of nanomaterials using charge-transfer reactions in electroactive self-assembled monolayers

Norman, Lana

07 1900

Les microcantileviers fonctionnalisés offrent une plateforme idéale pour la nano- et micro-mécanique et pour le développement de (bio-) capteurs tres sensible. Le principe d’opération consiste dans des évènements physicochimiques qui se passent du côté fonctionnalisé du microcantilevier induisant une différence de stress de surface entre les deux côtés du cantilevier qui cause une déflexion verticale du levier. Par contre, les facteurs et les phénomènes interfacials qui régissent la nature et l'intensité du stress de surface sont encore méconnus. Pour éclaircir ce phénomène, la première partie de cette thèse porte sur l'étude des réactions de microcantileviers qui sont recouverts d'or et fonctionnalisés par une monocouche auto-assemblée (MAA) électroactive. La formation d'une MAA de ferrocènylundécanethiol (FcC11SH) à la surface d'or d'un microcantilevier est le modèle utilisé pour mieux comprendre le stress de surface induit par l’électrochimie. Les résultats obtenus démontrent qu'une transformation rédox de la MAA de FcC11SH crée un stress de surface qui résulte dans une déflexion verticale du microcantilevier. Dépendamment de la flexibilité du microcantilevier, cette déflexion peut varier de quelques nanomètres à quelques micromètres. L’oxydation de cette MAA de FcC11SH dans un environnement d'ions perchlorate génère un changement de stress de surface compressive. Les résultats indiquent que la déflexion du microcantilevier est due à une tension latérale provenant d'une réorientation et d'une expansion moléculaire lors du transfért de charge et de pairage d’anions. Pour vérifier cette hypothèse, les mêmes expériences ont été répéteés avec des microcantileviers qui ont été couverts d'une MAA mixte, où les groupements électroactifs de ferrocène sont isolés par des alkylthiols inactifs. Lorsqu’un potentiel est appliqué, un courant est détecté mais le microcantilevier ne signale aucune déflexion. Ces résultats confirment que la déflexion du microcantilevier est due à une pression latérale provenant du ferrocènium qui se réorganise et qui crée une pression sur ses pairs avoisinants plutôt que du couplage d’anions. L’amplitude de la déflexion verticale du microcantilevier dépend de la structure moléculaire de la MAA et du le type d’anion utilisés lors de la réaction électrochimique. Dans la prochaine partie de la thèse, l’électrochimie et la spectroscopie de résonance de plasmon en surface ont été combinées pour arriver à une description de l’adsorption et de l’agrégation des n-alkyl sulfates à l’interface FcC11SAu/électrolyte. À toutes les concentrations de solution, les molécules d'agent tensio-actif sont empilées perpendiculairement à la surface d'électrode sous forme de monocouche condensé entrecroisé. Cependant, la densité du film spécifiquement adsorbé s'est avérée être affectée par l'état d'organisation des agents tensio-actifs en solution. À faible concentration, où les molécules d'agent tensio-actif sont présentes en tant que monomères solvatés, les monomères peuvent facilement s'adapter à l’évolution de la concentration en surface du ferrocènium lors du balayage du potential. Cependant, lorsque les molécules sont présentes en solution en tant que micelles une densité plus faible d'agent tensio-actif a été trouvée en raison de l'incapacité de répondre effectivement à la surface de ferrocenium générée dynamiquement. / Surface-functionalized microcantilevers provide an ideal platform for nano- and micro-mechanical actuation and highly sensitive sensing technologies. The basic principle of operation is that a chemical or physical event occurring at the functionalized surface of one side of the cantilever generates a surface stress difference (between the active functionalized and passive non-functionalized sides) that causes the cantilever to bend away from its resting position. However, the factors and phenomena contributing to both the nature and magnitude of the surface stress are not well understood. To this end, the first part of this thesis focused on investigating the potential-controlled actuation and surface stress properties of free-standing gold-coated microcantilevers functionalized with a redox-active self-assembled monolayer (SAM). A ferrocenylundecanethiolate (FcC11SAu) SAM on a gold-coated cantilever was used as a model system to investigate the surface stress generated by faradaic chemistry. The data obtained clearly demonstrates that the electrochemical transformation of a ferrocene moiety in a monomolecular organic film can generate a surface stress change of sufficient magnitude to deflect a microcantilever. In fact, depending on the flexibility of the microcantilever, the mechanical deflection resulting from the redox transformation of the surface-tethered ferrocene can range on the order of nanometers to micrometers. The oxidation of the FcC11SAu SAM in perchlorate electrolyte generates a compressive surface stress change. The microcantilever deflection is driven by the lateral tension resulting from molecular reorientation/volume expansion accompanying the charge-transfer and ion-pairing events. To verify this hypothesis, mixed SAM-modified microcantilevers, in which the electroactive ferrocenes are isolated from one another by an inert n-alkylthiolate matrix, were investigated. Under an applied potential, a Faradaic current was measured, but no microcantilever beam deflection was observed. This finding confirms that the cantilever responds to the lateral pressure exerted by an ensemble of re-orienting ferrocenium-bearing alkylthiolates upon each other rather than to individual anion pairing events. Changes in molecular structure and anion type can also be used to modulate the extent of micromechanical motion. In the next part of the dissertation, electrochemical measurements and surface plasmon resonance spectroscopy were combined to present a description of the adsorption and aggregation of n-alkyl sulfates at the FcC11SAu/electrolyte interface. At all bulk solution concentrations, the surfactant moieties packed perpendicular to the electrode surface in the form of an interdigitated condensed film. However, the density of the specifically adsorbed film was found to be affected by the organizational state of the surfactants in solution. At low concentrations, where the surfactant molecules are present as solvated monomers, the monomers can readily adapt to the changing ferrocenium concentration with the potential potential scan. However, when the molecules are present as micellar structures in solution, a lower surfactant packing density was found because of the inability to respond effectively to the dynamically generated surface ferroceniums. This research demonstrates the potential utility of charge-transfer interactions for organizing materials at solid interfaces and effecting micromechanical actuation using an electrifical stimulus.

Surface stress

Microcantilever

Ferrocene

Self-assembled monolayer

Electrochemistry

Surfactant aggregation

Surface plasmon resonance

Tension de surface

Ferrocène

Monocouches auto-assemblées

Microcantilevier

Électrochimie

Experiments on the Growth and Form of Icicles

Chen, Antony Szu-Han

27 March 2014

Icicles are a ubiquitous and picturesque feature of cold winter weather. Their familiar form emerges from a subtle interplay between the solidification dynamics of ice and the gravity-driven flow of the thin water film flowing over their evolving surface. The latent heat released by freezing is advected by the water film and ultimately carried away by the surrounding sub-zero air, which is also flowing. Like many processes far from equilibrium, icicle growth can exhibit nonlinear pattern formation. While scaling theory predicts that icicles converge to `platonic', self-similar shapes, natural icicles often exhibit regular ripple patterns about their circumference, which are due to a morphological instability. This thesis presents a comprehensive experimental study of icicles that sheds new light on the dynamics of their growth and the origin of their form. A table-top apparatus was designed and built for the controlled growth of icicles, under different conditions of temperature, water supply rate, ambient air motion, and water purity. Image analysis and Fourier methods were used to examine their morphology. Contrary to theoretical expectations, ripples do not appear on icicles made from pure water. Instead, ripples grow and travel on icicles made from salt solutions, even at very low concentrations. The addition of non-ionic surfactant or dissolved gases does not produce ripples, unless ionic impurities are also present. The ripple wavelength is independent of time and growth conditions. The ripple amplification rate and traveling velocity vary weakly with the ionic concentration, as do the tip and radial growth speeds of the icicle. While the tip and radial growth also depend on the ambient temperature and input mass flux, the ripple dynamics is not correlated with extrinsic conditions. If the ambient temperature or input mass flux is sufficiently low, the tip growth only advances for a short period of time before it ceases. After cessation, the shape of the icicle deviates increasingly from self-similarity. The most self-similar icicles are made from pure water with the surrounding air gently stirred, whereas icicles made from impure water in still air tend to grow multiple tips.

nonlinear dynamics

pattern formation

ice growth

heat transfer

fluid mechanics

thin film flow

non-equilibrium processes

morphological instability

natural phenomenon

table-top experiment

ionic impurities

surfactant effects

dissolved gases

icicles

stalactites

0605

Synthesis and characterisation of metal (Fe, Ga, Y) doped alumina and gallium oxide nanostructures

Zhao, Yanyan

January 2008

It is well known that nanostructures possess unique electronic, optical, magnetic, ferroelectric and piezoelectric properties that are often superior to traditional bulk materials. In particular, one dimensional (1D) nanostructured inorganic materials including nanofibres, nanotubes and nanobelts have attracted considerable attention due to their distinctive geometries, novel physical and chemical properties, combined effects and their applications to numerous areas. Metal ion doping is a promising technique which can be utilized to control the properties of materials by intentionally introducing impurities or defects into a material. γ-Alumina (Al2O3), is one of the most important oxides due to its high surface area, mesoporous properties, chemical and thermal properties and its broad applications in adsorbents, composite materials, ceramics, catalysts and catalyst supports. γ-Alumina has been studied intensively over a long period of time. Recently, considerable work has been carried out on the synthesis of 1D γ-alumina nanostructures under various hydrothermal conditions; however, research on the doping of alumina nanostructures has not been forthcoming. Boehmite (γ-AlOOH) is a crucial precursor for the preparation of γ-Alumina and the morphology and size of the resultant alumina can be manipulated by controlling the growth of AlOOH. Gallium (Ga) is in the same group in the periodic table as aluminum. β-Gallium (III) oxide (β-Ga2O3), a wide band gap semiconductor, has long been known to exhibit conduction, luminescence and catalytic properties. Numerous techniques have been employed on the synthesis of gallium oxide in the early research. However, these techniques are plagued by inevitable problems. It is of great interest to explore the synthesis of gallium oxide via a low temperature hydrothermal route, which is economically efficient and environmentally friendly. The overall objectives of this study were: 1) the investigation of the effect of dopants on the morphology, size and properties of metal ion doped 1D alumina nanostructures by introducing dopant to the AlOOH structure; 2) the investigation of impacts of hydrothermal conditions and surfactants on the crystal growth of gallium oxide nanostructures. To achieve the above objectives, trivalent metal elements such as iron, gallium and yttrium were employed as dopants in the study of doped alumina nanostructures. In addition, the effect of various parameters that may affect the growth of gallium oxide crystals including temperature, pH, and the experimental procedure as well as different types of surfactants were systematically investigated. The main contributions of this study are: 1) the systematic and in-depth investigation of the crystal growth and the morphology control of iron, gallium and yttrium doped boehmite (AlOOH) under varying hydrothermal conditions, as a result, a new soft-chemistry synthesis route for the preparation of one dimensional alumina/boehmite nanofibres and nanotubes was invented; 2) systematic investigation of the crystal growth and morphology and size changes of gallium oxide hydroxide (GaOOH) under varying hydrothermal conditions with and without surfactant at low temperature; We invented a green hydrothermal route for the preparation of α-GaOOH or β-GaOOH micro- to nano-scaled particles; invented a simple hydrothermal route for the direct preparation of γ-Ga2O3 from aqueous media at low temperature without any calcination. The study provided detailed synthesis routes as well as quantitative property data of final products which are necessary for their potential industrial applications in the future. The following are the main areas and findings presented in the study: • Fe doped boehmite nanostructures This work was undertaken at 120ºC using PEO surfactant through a hydrothermal synthesis route by adding fresh iron doped aluminium hydrate at regular intervals of 2 days. The effect of dopant iron, iron percentage and experimental procedure on the morphology and size of boehmite were systematically studied. Iron doped boehmite nanofibres were formed in all samples with iron contents no more than 10%. Nanosheets and nanotubes together with an iron rich phase were formed in 20% iron doped boehmite sample. A change in synthesis procedure resulted in the formation of hematite large crystals. The resultant nanomaterials were characterized by a combination of XRD, TEM, EDX, SAED and N2 adsorption analysis. • Growth of pure boehmite nanofibres/nanotubes The growth of pure boehmite nanofibres/nanotubes under different hydrothermal conditions at 100ºC with and without PEO surfactant was systematically studied to provide further information for the following studies of the growth of Ga and Y doped boehmite. Results showed that adding fresh aluminium hydrate precipitate in a regular interval resulted in the formation of a mixture of long and short 1D boehmite nanostructures rather than the formation of relatively longer nanofibres/nanotubes. The detailed discussion and mechanism on the growth of boehmite nanostructure were presented. The resultant boehmite samples were also characterized by N2 adsorption to provide further information on the surface properties to support the proposed mechanism. • Ga doped boehmite nanostructures Based on this study on the growth of pure boehmite nanofibre/nanotubes, gallium doped boehmite nanotubes were prepared via hydrothermal treatment at 100ºC in the presence of PEO surfactant without adding any fresh aluminium hydrate precipitate during the hydrothermal treatment. The effect of dopant gallium, gallium percentage, temperature and experimental procedure on the morphology and size of boehmite was systematically studied. Various morphologies of boehmite nanostructures were formed with the increase in the doping gallium content and the change in synthesis procedure. The resultant gallium doped boehmite nanostructures were characterized by TEM, XRD, EDX, SAED, N2 adsorption and TGA. • Y doped boehmite nanostructures Following the same synthesis route as that for gallium doped boehmite, yttrium doped boehmite nanostructures were prepared at 100ºC in the presence of PEO surfactant. From the study on iron and gallium doped boehmite nanostructures, it was noted both iron and gallium cannot grow with boehmite nanostructure if iron nitrate and gallium nitrate were not mixed with aluminium nitrate before dissolving in water, in particular, gallium and aluminium are 100% miscible. Therefore, it’s not necessary to study the mixing procedure or synthesis route on the formation of yttrium doped boehmite nanostructures in this work. The effect of dopant yttrium, yttrium percentage, temperature and surfactant on the morphology and size of boehmite were systematically studied. Nanofibres were formed in all samples with varying doped Y% treated at 100ºC; large Y(OH)3 crystals were also formed at high doping Y percentage. Treatment at elevated temperatures resulted in remarkable changes in size and morphology for samples with the same doping Y content. The resultant yttrium doped boehmite nanostructures were characterized by TEM, XRD, EDX, SAED, N2 adsorption and TGA. • The synthesis of Gallium oxide hydroxide and gallium oxide with surfactant In this study, the growth of gallium oxide hydroxide under various hydrothermal conditions in the presence of different types of surfactants was systematically studied. Nano- to micro-sized gallium oxide hydroxide was prepared. The effect of surfactant and synthesis procedure on the morphology of the resultant gallium oxide hydroxide was studied. β-gallium oxide nanorods were derived from gallium oxide hydroxide by calcination at 900ºC and the initial morphology was retained. γ-gallium oxide nanotubes up to 65 nm in length, with internal and external diameters of around 0.8 and 3.0 nm, were synthesized directly in solution with and without surfactant. The resultant nano- to micro-sized structures were characterized by XRD, TEM, SAED, EDX and N2 adsorption. • The synthesis of gallium oxide hydroxide without surfactant The aim of this study is to explore a green synthesis route for the preparation of gallium oxide hydroxide or gallium oxide via hydrothermal treatment at low temperature. Micro to nano sized GaOOH nanorods and particles were prepared under varying hydrothermal conditions without any surfactant. The resultant GaOOH nanomaterials were characterized by XRD, TEM, SAED, EDX, TG and FT-IR. The growth mechanism of GaOOH crystals was proposed.

Relation structure-transport dans des membranes et matériaux modèles pour pile à combustible / Membranes for fuel cells : structure-transport relation in models materials

Berrod, Quentin

19 December 2013

L’optimisation des performances d’une pile à combustible (PEMFC) requiert la compréhension microscopique des mécanismes de transport de l’eau et du proton confinés au sein de la membrane électrolyte polymère. La membrane est un matériau nanostructuré chargé, caractérisé par une dynamique de l’eau et du proton complexe et multi-échelle étroitement corrélée à la morphologie confinante. Nous nous sommes intéressés à la relation structure – transport dans i) L’Aquivion, un ionomère perfluorosulfonique récent présentant de bonnes performances en pile, ii) des systèmes «modèles» auto-assemblés de tensioactifs perfluorés formant des phases lamellaires et hexagonales et iii) une nouvelle membrane hybride préparée par dopage en tensioactif. La nano-structuration des différents systèmes a été étudiée par diffusion de rayonnement (X et neutrons), pour caractériser l’évolution de la structure (géométrie de la matrice hôte, taille de confinement) avec l’hydratation. Ensuite, nous avons sondé la dynamique de l’eau à l’échelle moléculaire (de la picoseconde à la nanoseconde) par diffusion quasi-élastique des neutrons (QENS) et à l’échelle micrométrique par RMN à gradients de champs pulsés. La comparaison membranes commerciales / systèmes modèles permet de discuter l’impact de la connectivité, du confinement et de la géométrie sur le transport ionique. Enfin, des membranes hybrides à fort potentiel ont été obtenues par dopage du Nafion et de l’Aquivion avec des tensioactifs. Ces nouveaux matériaux ouvrent une voie prometteuse pour la préparation de membranes polymères fortement anisotropes avec des chemins de conduction préférentiellement orientés. / The optimization of the Fuel Cell’s performances (PEMFC) requires a microscopic understanding of the water and proton’s transport mechanism, which are confined in a polymer electrolyte membrane. The latter is nanostructured, charged and characterized by a complex and multi-scale water and proton dynamics, closely correlated to the confining morphology. We studied the structure-transport interplay in i) the Aquivion, a recent perfluorosulfonic ionomer exhibiting good performances in fuel cell, ii) “model” systems of perfluorosulfonic surfactants, which self-assemble in lamellar and hexagonal phases and iii) a new hybrid membrane doped with surfactant. The nanostructuration of the different systems has been studied by neutron and X-ray scattering, to characterize the structural evolution (host matrix geometry, confinement sizes) with hydration. Then, we probe the water dynamics at the molecular level (from picosecond to nanosecond) with Quasi-Elastic Neutron Scattering (QENS) and at the micrometric scale with Pulsed Field Gradient NMR. The comparison of commercial membranes and model systems bring new insight on the impact of the connectivity, the confinement and the geometry, on the ionic transport. Finally, high potential hybrid membranes have been obtained by doping Nafion and Aquivion with surfactants. Those new materials open a promising way for the preparation of highly anisotropic polymer membrane, with conducting path preferentially oriented.

Matrice confinée chargée

Tensioactifs fluorés

Pile à combustible

Matériaux modèles

RMN gradient de champ QENS

Relaxométrie

Multi scale dynamic of proton and water

Confined and charged water

Fluored surfactant

Fuel cell

Models materials

Pulsed field gradient NMR

Relaxometry

530

[en] MOLECULAR DYNAMICS OF PREDNISOLONE ADSORPTION ON A LUNG SURFACTANT MODEL / [pt] DINÂMICA MOLECULAR DA ADSORÇÃO DE PREDNISOLONA EM UM MODELO DE SURFACTANTE PULMONAR

EVELINA DUNESKA ESTRADA LOPEZ

28 May 2018

[pt] A simulação da adsorção da prednisolona em um modelo de surfactante pulmonar foi realizada com sucesso usando dinâmica molecular coarse grained a uma temperatura de 310 K. O modelo coarse grained da prednisolona foi parametrizado usando o modelo do colesterol e validado utilizando cálculos de coeficientes de partição octanol-água e coeficientes de difusão lateral. O coeficiente de partição octanol-água calculado para prednisolona a 298 K é 3,9 mais ou menos 1,6 que possui um acordo razoável com o valor experimental. O coeficiente de difusão lateral da prednisolona na monocamada mista de DPPC/POPC é estimado ser (6 mais ou menos 4) x10(-7) cm(2) s(-1) a 20 mN m(-1), o que está de acordo com o encontrado para o colesterol. A monocamada mista de DPPC/POPC foi utilizada como modelo de surfactante pulmonar onde moléculas de prednisolona foram adsorvidas formando nanoagregados. Os nanoagregados de prednisolona foram transferidos dentro da monocamada mista DPPC/POPC sendo espalhados na tensão superficial de 20 mN m(-1). A 0 e 10 mN m(-1) os nanoagregados de prednisolona induzem o colapso da monocamada mista DPPC/POPC formando bicamadas. A implicação deste trabalho é que a prednisolona pode apenas ser administrada com surfactante pulmonar utilizando baixas frações em massa de prednisolona por lipídio (menor que 10 por cento). Com frações elevadas, o colapso inativa as propriedades do surfactante pulmonar pela formação de uma bicamada. Os resultados desta pesquisa podem ser utilizados para o desenvolvimento de novos tratamentos clínicos de doenças como a síndrome da angústia respiratória do recém-nascido, asma e doença pulmonar obstrutiva crônica. / [en] The simulation of prednisolone adsorption on a lung surfactant model was successfully performed using coarse grained molecular dynamics at 310 K (dynamics first performed). The coarse grained model for prednisolone was parameterized using a well-established cholesterol model and validated by using calculations of octanol–water partition coefficients and lateral diffusion coefficients. The calculated octanol–water partition coefficient of prednisolone at 298 K is 3.9 more or less 1.6, which is in reasonable agreement with experiment. The lateral diffusion coefficient of prednisolone in the DPPC/POPC mixed monolayer is estimated to be (6 more or less 4) x10(-7) cm(2) s(-1) at 20 mN m(-1), which is in agreement with that found for cholesterol. The DPPC/POPC mixed monolayer was used as lung surfactant model where prednisolone molecules were adsorbed forming nanoaggregates. The nanoaggregates of prednisolone were transferred into the DPPC/POPC mixed monolayer being spread at the surface tension of 20 mN m(-1). At 0 and 10 mN m(-1) , the prednisolone nanoaggregates induce the collapse of the DPPC/POPC mixed monolayer forming a bilayer. The implications of this work are that prednisolone may only be administered with lung surfactant by using low mass fractions of prednisolone per lipid (less than 10 percent). And, with high fractions, the collapse inactivates the properties of the lung surfactant by forming a bilayer. The results of this research can be used to develop new clinical treatments for diseases such as respiratory distress syndrome of the newborn, asthma and chronic obstructive pulmonary disease.

[pt] ESPALHAMENTO

[en] SCATTERING

[pt] COLAPSO

[en] COLLAPSE

[pt] PREDNISOLONA

[en] PREDNISOLONE

[pt] DINAMICA MOLECULAR

[en] MOLECULAR DYNAMICS

[pt] SURFACTANTE PULMONAR

[en] LUNG SURFACTANT

[pt] MONOCAMADA FOSFOLIPIDICA

[en] PHOSPHOLIPID MONOLAYER

[pt] MODELO COARSE GRAINED

[en] COARSE GRAINED MODEL

Influ?ncia de tensoativos n?o i?nicos na destila??o molecular de petr?leo / Influence of nonionic surfactants in molecular distillation of petroleum

Lucena, Izabelly Larissa

12 July 2013

Made available in DSpace on 2015-03-03T15:02:47Z (GMT). No. of bitstreams: 1 IzabellyLL_TESE.pdf: 7496453 bytes, checksum: d39fc896ff5d9d4982952835ef786c26 (MD5) Previous issue date: 2013-07-12 / The molecular distillation is show as an alternative for separation and purification of various kinds of materials. The process is a special case of evaporation at high vacuum, in the order from 0.001 to 0.0001 mmHg and therefore occurs at relatively lower temperatures, preserves the material to be purified. In Brazil, molecular distillation is very applied in the separation of petroleum fractions. However, most studies evaluated the temperature of the evaporator, condenser temperature and flow such variables of the molecular distillation oil. Then, to increase the degree of recovery of the fraction of the distillate obtained in the process of the molecular distillation was evaluated the use nonionic surfactants of the class of nonylphenol ethoxylate, molecules able to interact in the liquid-liquid and liquid-vapor interface various systems. In this context, the aim of this work was to verify the influence of commercial surfactant (Ultranex-18 an Ultranex-18-50) in the molecular distillation of a crude oil. The physicochemical characterization of the oil was realized and the petroleum shown an API gravity of 42?, a light oil. Initially, studied the molecular distillation without surfactant using star design experimental (2H ? ) evaluated two variables (evaporator temperature and condenser temperature) and answer variable was the percentage in distillate obtained in the process (D%). The best experimental condition to molecular distillation oil (38% distillate) was obtained at evaporator and condenser temperatures of 120 ?C and 10 ? C, respectively. Subsequently, to determine the range of surfactant concentration to be applied in the process, was determined the critical micellar concentration by the technique of scattering X-ray small angle (SAXS). The surfactants Ultranex-18 an Ultranex-18-50 shown the critical micelle concentration in the range of 10-2 mol/L in the hydrocarbons studied. Then, was applied in the study of distillation a concentration range from 0.01 to 0.15 mol/L of the surfactants (Ultranex- 18 and 50). The use of the nonionic surfactant increased the percentage of hydrocarbons in the range from 5 to 9 carbons in comparison to the process carried out without surfactant, and in some experimental conditions the fraction of light compounds in the distilled was over 700% compared to the conventional process. The study showed that increasing the degree of ethoxylation of Ultranex18 to Ultranex-50, the compounds in the range of C5 to C9 reduced the percentage in the distilled, since the increase of the hydrophilic part of the surfactant reduces its solubility in the oil. Finally, was obtained an increase in the degree of recovery of light hydrocarbons, comparing processes with and without surfactant, obtained an increase of 10% and 4% with Ultranex-18 and Ultranex-50, respectively. Thus, it is concluded that the Ultranex- 18 surfactant showed a higher capacity to distillation compared with Ultranex-50 and the application of surfactant on the molecular distillation from petroleum allowed for a greater recovery of light compounds in distillate / A destila??o molecular apresenta-se como uma alternativa para separa??o e purifica??o de diversos tipos de materias. O processo ? um caso especial de evapora??o a alto v?cuo, na ordem 0,001 a 0,0001 mmHg, e consequentemente, ocorre ? temperaturas relativamente mais baixas, preservando ao m?ximo o material a ser purificado. No Brasil, a destila??o molecular ? muito aplicada na separa??o de fra??es de petr?leo. No entanto, boa parte dos estudos relacionados a destila??o molecular de petr?leo avalia apenas as vari?veis do processo, tais como: a temperatura do evaporador, temperatura do condensador, vaz?o e etc. Dessa forma, com o prop?sito de favorecer a destila??o molecular, visando aumentar o grau de recupera??o da fra??o do destilado obtido no processo, avaliou-se a aplica??o de tensoativos n?o i?nicos da classe do nonilfenol etoxilado, uma vez que tais mol?culas apresentam a capacidade de interagir na interface l?quido-l?quido e l?quido-vapor de diversos sistemas. Portanto, o objetivo deste trabalho foi verificar a influ?ncia de tensoativo comerciais do tipo Ultranex-18 e Ultranex-50 na destila??o molecular de um petr?leo bruto. Nesse estudo, realizou-se a caracteriza??o f?sico-qu?mica do petr?leo a ser destilado, determinando-se que o mesmo apresentava um grau API de 42?, o que confere a amostra a ser destilada uma caracter?stica de fra??o leve. Na etapa do estudo das destila??es moleculares realizadas sem tensoativo, aplicou-se um planejamento estrela (2K ? ) com duas vari?veis (temperatura do evaporador e temperatura do condensador), tendo como resposta a porcentagem de destilado obtida no processo (%D). Verificou-se que a melhor condi??o experimental para a destila??o molecular do petr?leo estudado foi aplicando uma temperatura do evaporador de 120?C e do condensador de 10?C, obtendo-se uma porcentagem de destilado de 38 %. Posteriormente, para determinar uma faixa de concentra??o de tensoativo a ser aplicado no processo determinou-se a concentra??o micelar critica aplicando a t?cnica de espalhamento de raio-X de baixo ?ngulo (SAXS). Atrav?s da t?cnica, constatou-se que para os tensoativos da classe do nonilfenois etoxilados a concentra??o micelar cr?tica encontra-se na faixa de 10-2 mol/L para os hidrocarbonetos estudados. A partir dessa constata??o, aplicou-se no estudo das destila??es com tensoativo (Ultranex-18 e 50) uma faixa de concentra??o entre 0,01 a 0,15 mol/L. Nesta etapa, verificou-se que a presen?a do tensoativo n?o i?nico aumentou a destila??o de hidrocarbonetos na faixa de 5 a 9 carbonos em compara??o ao processo realizado sem tensoativo, e que em alguns casos a fra??o de compostos leves no destilado do processo foi superior a 700 % em rela??o ao processo convencional. O estudo mostrou que o aumento do grau de etoxila??o do Ultranex-18 para o Ultranex-50, reduziu a porcentagem de compostos destilados na faixa de C5 a C9, uma vez que o aumento da parte hidrof?lica do tensoativo reduz sua solubilidade no petr?leo. Finalmente, verificou-se que o aumento no grau de recupera??o de hidrocarbonetos leves, comparando os processos com o tensoativo e sem tensoativo, resultou em um aumento de 10 % para o processo empregando o Ultranex-18 e 4% para o Ultranex-50. Dessa forma, conclui-se que o Ultranex-18 apresentou maior capacidade de destila??o frente ao Ultranex-50 e que a aplica??o de tensoativo na destila??o molecular de petr?leo favoreceu o processo, j? que houve o aumento da concentra??o de compostos leves obtidos

CNPQ::ENGENHARIAS::ENGENHARIA QUIMICA

Estudo da cristaliza??o de parafinas em sistemas solventes/tensoativos/?gua

Gomes, Erika Adriana de Santana

30 December 2009

Made available in DSpace on 2014-12-17T15:01:49Z (GMT). No. of bitstreams: 1 ErikaASG_TESE_partes_autorizadas.pdf: 3587859 bytes, checksum: 8731a4ebad1b8f6f11b36c879b4a1a76 (MD5) Previous issue date: 2009-12-30 / The WAT is the temperature at the beginning of the appearance of wax crystals. At this temperature the first wax crystals are formed by the cooling systems paraffin / solvents. Paraffins are composed of a mixture of saturated hydrocarbons of high molecular weight. The removal of petroleum from wells and the production lines means a surcharge on produced oil, thus solubilize these deposits formed due to modifications of thermodynamics has been a constant challenge for companies of oil exploration. This study combines the paraffin solubilization by microemulsion systems, the determination of WAT systems paraffin / solvent and performance of surfactant in reducing the crystallization. We used the methods: rheological and the photoelectric signal, validating the latter which was developed to optimize the data obtained due to sensitivity of the equipment used. Methods developed for description of wax precipitation are often in poor agreement with the experimental data, they tend to underestimate the amount of wax at temperatures below the turbidity point. The Won method and the Ideal solution method were applied to the WAT data obtained in solvent systems, best represented by the second interaction of Won method using the solvents naphtha, hexane and LCO. It was observed that the results obtained by WAT photoelectric signal when compared with the viscosity occur in advance, demonstrating the greatest sensitivity of the method developed. The ionic surfactant reduced the viscosity of the solvent systems as it acted modifying the crystalline structure and, consequently, the pour point. The curves show that the WAT experimental data is, in general, closer to the modeling performed by the method of Won than to the one performed by the ideal solution method, because this method underestimates the curve predicting the onset of paraffin hydrocarbons crystallization temperature. This occurs because the actual temperature measured was the crystallization temperature and the method proposes the fusion temperature measurement. / A TIAC ? a temperatura de in?cio do aparecimento dos cristais de parafina. Nesta temperatura os primeiros cristais de parafina s?o formados, pelo resfriamento de sistemas parafina/solventes. As parafinas s?o compostas de uma mistura de hidrocarbonetos saturados de alto peso molecular. A remo??o de parafinas dos po?os e das linhas de produ??o significa um custo adicional ao petr?leo produzido, portanto solubilizar estes dep?sitos formados decorrentes das modifica??es termodin?micas tem sido um desafio constante das empresas exploradoras de petr?leo. Este estudo alia a solubiliza??o paraf?nica por sistemas microemulsionados, ? determina??o da TIAC dos sistemas parafina/solvente e a atua??o do tensoativo na redu??o da cristaliza??o. Utilizaram-se os m?todos: reol?gico e o do sinal fotoel?trico, validando este ?ltimo o qual foi desenvolvido visando aperfei?oar os dados obtidos devido a sensibilidade do equipamento utilizado. M?todos desenvolvidos para descri??o da precipita??o da cera est?o freq?entemente em pobre concord?ncia com os dados experimentais; eles tendem a subestimar a quantidade de cera ?s temperaturas abaixo do ponto de turbidez. Foram aplicados os m?todos de Won e o da solu??o ideal aos dados de TIAC da parafina obtidos em sistemas com solventes, sendo melhor representado pela segunda intera??o do m?todo de Won com os solventes: nafta, hexano e LCO. Foi observado que os resultados de TIAC obtidos pelo sinal fotoel?trico quando comparados com a viscosidade, ocorrem antecipadamente, demonstrando a maior sensibilidade do m?todo desenvolvido. O tensoativo i?nico reduziu a viscosidade dos sistemas paraf?nicos, pois ele atuou modificando a estrutura cristalina, conseq?entemente o ponto de fluidez. As curvas que representam os dados experimentais da TIAC est?o, de maneira geral, mais pr?ximas da modelagem realizada pelo m?todo de Won do que da solu??o ideal, pois este m?todo subestima a curva de predi??o do in?cio da temperatura de cristaliza??o da parafina com os hidrocarbonetos. Isto ocorre porque a temperatura real medida foi a de cristaliza??o, e a proposta pelos m?todos ? a de fus?o

Parafina

temperatura

cristaliza??o

microemuls?es

tensoativo

viscosidade

modelagem

termodin?mica

m?todo

fotoel?trico

solventes

Paraffin

solvents

CNPQ::ENGENHARIAS::ENGENHARIA QUIMICA

Equil?brio l?quido-l?quido de sistemas aquosos com tensoativos polietoxilados: dados experimentais e modelagem

Ara?jo, Alessandro Alisson de Lemos

11 November 2013

Made available in DSpace on 2014-12-17T15:01:56Z (GMT). No. of bitstreams: 1 AlessandroALA_TESE.pdf: 2166690 bytes, checksum: 87b921d322f56a3c11d668a0ad8d9341 (MD5) Previous issue date: 2013-11-11 / Coordena??o de Aperfei?oamento de Pessoal de N?vel Superior / The nonionic surfactants when in aqueous solution, have the property of separating into two phases, one called diluted phase, with low concentration of surfactant, and the other one rich in surfactants called coacervate. The application of this kind of surfactant in extraction processes from aqueous solutions has been increasing over time, which implies the need for knowledge of the thermodynamic properties of these surfactants. In this study were determined the cloud point of polyethoxylated surfactants from nonilphenolpolietoxylated family (9,5 , 10 , 11, 12 and 13), the family from octilphenolpolietoxylated (10 e 11) and polyethoxylated lauryl alcohol (6 , 7, 8 and 9) varying the degree of ethoxylation. The method used to determine the cloud point was the observation of the turbidity of the solution heating to a ramp of 0.1 ? C / minute and for the pressure studies was used a cell high-pressure maximum ( 300 bar). Through the experimental data of the studied surfactants were used to the Flory - Huggins models, UNIQUAC and NRTL to describe the curves of cloud point, and it was studied the influence of NaCl concentration and pressure of the systems in the cloud point. This last parameter is important for the processes of oil recovery in which surfactant in solution are used in high pressures. While the effect of NaCl allows obtaining cloud points for temperatures closer to the room temperature, it is possible to use in processes without temperature control. The numerical method used to adjust the parameters was the Levenberg - Marquardt. For the model Flory- Huggins parameter settings were determined as enthalpy of the mixing, mixing entropy and the number of aggregations. For the UNIQUAC and NRTL models were adjusted interaction parameters aij using a quadratic dependence with temperature. The parameters obtained had good adjust to the experimental data RSMD < 0.3 %. The results showed that both, ethoxylation degree and pressure increase the cloudy points, whereas the NaCl decrease / Os tensoativos n?o i?nicos, quando em solu??o aquosa, apresentam a propriedade de separa??o em duas fases, sendo uma denominada de fase dilu?da, baixa concentra??o em tensoativo, e a outra rica em tensoativo denominada de coacervato. A aplica??o deste tipo de tensoativo nos processos de extra??o de solutos de meios aquosos vem aumentando o que implica na necessidade do conhecimento das propriedades termodin?micas desses tensoativos. Neste trabalho foram determinados os pontos de n?voa dos tensoativos polietoxilados, da fam?lia do nonilfenolpolietoxilado variando o grau de etoxila??o (9,5;10;11;12 e 13), da fam?lia do octilfenolpolietoxilado variando o grau de etoxila??o (10 e 11) e do ?lcool laur?lico polietoxilado nos graus de etoxila??o (6;7;8 e 9). O m?todo utilizado para determina??o do ponto de n?voa foi a observa??o do turvamento da solu??o ao aquecer o sistema a uma rampa de 0,1oC/minuto, e no estudo da press?o foi utilizada uma c?lula de alta press?o, m?ximo (300 bar). Atrav?s dos dados experimentais obtidos dos respectivos tensoativos, foram utilizados os modelos de Flory-Huggins, UNIQUAC e NRTL para descrever as curvas do ponto de n?voa dos referidos tensoativos. Foram tamb?m estudados a influ?ncia da concentra??o do NaCl e da press?o no ponto de n?voa. Este ?ltimo par?metro ? importante para os processos de recupera??o avan?ada de petr?leo nos quais os tensoativos em solu??o s?o submetidos a press?es elevadas. Enquanto que o efeito do NaCl permite obter pontos de n?voa a temperaturas mais pr?xima da temperatura ambiente viabilizando sua utiliza??o em processos sem controle de temperatura. O m?todo num?rico utilizado para ajustar os par?metros foi o Levenberg-Marquardt. Para o modelo de Flory-Huggins foram determinados par?metros de ajuste como a entalpia da mistura, entropia da mistura e o n?mero de agrega??o. Para os modelos UNIQUAC e NRTL foram ajustados par?metros de intera??o aij utilizando uma depend?ncia quadr?tica com a temperatura. Os par?metros obtidos tiveram bons ajustes aos dados experimentais com RMSD < 0,3%. Os resultados mostraram que tanto a etoxila??o quanto a press?o aumentam o ponto de n?voa do tensoativo, enquanto que o NaCl diminui

CNPQ::ENGENHARIAS::ENGENHARIA QUIMICA

Sistemas microemulsionados aplicados ? remo??o da cor de efluente t?xtil

Beltrame, Leoc?dia Terezinha Cordeiro

21 October 2006

Made available in DSpace on 2014-12-17T15:01:57Z (GMT). No. of bitstreams: 1 LeocadiaTCB.pdf: 1594369 bytes, checksum: da7a2bc5860922178cae36e104bfbd40 (MD5) Previous issue date: 2006-10-21 / Conselho Nacional de Desenvolvimento Cient?fico e Tecnol?gico / Effluent color resulting from textile dyeing processes has been one of the biggest environmental problems faced by the textile industry. In particular, reactive dyes are highly resistant to conventional wastewater treatment methods. New technologies have been contemplated, some of which have been applied in industrial treatment plants, but color removal has not been efficiently attained. Since microemulsion systems provide good results in heavy metals and proteins extraction processes, their use in dyes extraction has been suggested and investigated. In this work, a real textile wastewater from an exhaustion dyebath has been treated, which contains the following reactive dyes: Procion Yellow H-E4R (CI Reactive Yellow 84), Procion Blue H-ERD (CI Reactive Blue 160) and Procion Red H-E3B (CI Reactive Red 120), in addition to auxiliary compounds normally found in dyeing processes with reactive dyes. The dyes Remazol Blue RR and Remazol Turquoise Blue G (Reactive Blue 21) have also been examined in view of the presence of heavy metals in these molecules. The microemulsion system comprised dodecyl ammonium chloride (as a cationic surfactant), water or wastewater as aqueous phase, kerosene as oil phase, and one of the following alcohols as cosurfactant: isoamyl alcohol, n-butyl alcohol and n-octyl alcohol. The pseudo-ternary diagrams were constructed in order to define Winsor s equilibrium regions. The influence of parameters such as pH, C/S (cosurfactant/surfactant) ratio, distribution coefficient, initial dye concentration, salinity, temperature, phases relative amounts, loading capacity of the microemulsion phase and dye reextraction rate has also been investigated. An experimental planning (Scheff? Net) was used to optimize the extraction process. The removal of color and metals reached levels as high as 99% / A cor do efluente resultante dos processos de tingimento tem sido um dos principais problemas ambientais enfrentados pela ind?stria t?xtil. De modo especial, efluentes contendo corantes reativos s?o altamente resistentes aos processos de tratamento convencionais. Novas tecnologias t?m sido buscadas, algumas j? em escala industrial, por?m nem sempre ? poss?vel atingir a efici?ncia desejada. Por serem utilizadas de forma eficiente em processos de extra??o de metais e de prote?nas, buscou-se utilizar as microemuls?es na extra??o de corantes. Para este estudo, um efluente real foi examinado, consistindo no banho de exaust?o de um processo de tingimento contendo os seguintes corantes: Procion Amarelo H-E4R (CI Reactive Yellow 84), Procion Azul H-ERD (CI Reactive Blue 160) e Procion Vermelho H-E3B (CI Reactive Red 120), al?m de auxiliares normalmente encontrados em processos de tingimento com corantes reativos. Para estudar a remo??o de metais ligados ?s mol?culas dos corantes, utilizaram-se ainda os corantes Remazol Azul RR e Remazol Azul Turquesa G (Reactive Blue 21). Os sistemas de microemuls?o foram formados pelo cloreto de dodecilam?nio (tensoativo cati?nico), ?gua ou efluente como fase aquosa, querosene como fase oleosa e um dos seguintes ?lcoois como cotensoativos: ?lcool isoam?lico, n-butanol e n-octanol. Os diagramas pseudo-tern?rios, representativos dos sistemas microemulsionados em estudo, foram desenvolvidos a fim de delimitar as regi?es de exist?ncia de equil?brio de fases (sistema de classifica??o Winsor). Verificou-se a influ?ncia de par?metros como: pH, raz?o C/T (cotensoativo/tensoativo), coeficiente de distribui??o, concentra??o inicial de corante, salinidade, temperatura, rela??o das fases, capacidade de carga da fase de microemuls?o e reextra??o do corante. Uma metodologia de planejamento experimental (Rede de Scheff?) foi utilizada para otimizar a extra??o. A remo??o da cor e de metais alcan?ou ?ndices de extra??o superiores a 99%

Corantes reativos

Cobre

Banho de exaust?o

Metais pesados

Extra??o

CIELAB

Tensoativo

Cotensoativo

Winsor

Reactive dyes

Copper

Exhaustion bath

Heavy Metals

Extraction

CIELAB

Surfactant

Cosurfactant

Winsor

CNPQ::ENGENHARIAS::ENGENHARIA QUIMICA