Advanced low temperature metal hydride materials for low temperature proton exchange membrane fuel cell application

Ntsendwana, Bulelwa

January 2010

<p>Energy is one of the basic needs of human beings and is extremely crucial for continued development of human life. Our work, leisure and our economic, social and physical welfare all depend on the sufficient, uninterrupted supply of energy. Therefore, it is essential to provide adequate and affordable energy for improving human welfare and raising living standards. Global concern over environmental climate change linked to fossil fuel consumption has increased pressure to generate power from renewable sources [1]. Although substantial advances in renewable energy technologies have been made, significant challenges remain in developing integrated renewable energy systems due primarily to mismatch between load demand and source capabilities [2]. The output from renewable energy sources such as photo-voltaic, wind, tidal, and micro-hydro fluctuate on an hourly, daily, and seasonal basis. As a result, these devices are not well suited for directly powering loads that require a uniform and uninterrupted supply of input energy.</p>

Hydrogen energy

Polymer Exchange Membrane Fuel Cell

Solid state hydrogen storage

Metal hydrides

AB5 hydride-forming alloy

Ce-substituted LaNi5

Surface modification

Kinetics

Thermodynamics

Pressure-Composition Isotherm

Thermal conductivity

Heat and Mass transfer.

Carbon nanotubes for organic electronics

Goh, Roland Ghim Siong

January 2008

This thesis investigated the use of carbon nanotubes as active components in solution processible organic semiconductor devices. We investigated the use of functionalized carbon nanotubes in carbon nanotubes network transistors (CNNFET) and in photoactive composites with conjugated polymers. For CNNFETs, the objective was to obtain detailed understanding of the dependence of transistor characteristics on nanotubes bundle sizes, device geometry and processing. Single walled carbon nanotubes were functionalized by grafting octadecylamine chains onto the tubes, which rendered them dispersible in organic solvents for solution processing. To investigate the dependence of electronic properties of carbon nanotubes networks on bundle size, we developed a centrifugal fractionation protocol that enabled us to obtain nanotube bundles of different diameters. The electronic properties of networks of nanotube bundles deposited from solution were investigated within a CNNFET device configuration. By comparing devices with different degree of bundling we elucidated the dependence of key device parameters (field effect mobility and on/off ratio) on bundle sizes. We further found that, in contrast to traditional inorganic transistors, the electronic properties of the CNNFETs were dominated by the channel rather than contact resistance. Specifically, the apparent mobility of our devices increased with decreasing channel length, suggesting that the charge transport properties of CNNFETs are bulk rather than contacts dominated. This meant that charge traps in the channel of the device had a significant effect on transport properties. We found that charge traps in the channel region introduced by adsorbed oxygen and silanol groups on the SiO2 surface were responsible for the dominant p-type conductance in as-fabricated devices. Based on this understanding, we demonstrated the p-type to n-type conversion of the transistor characteristics of CNNFETs by depositing nanotubes on electron-trapfree dielectric surfaces. Finally, by combining annealing and surface treatment, we fabricated CNNFETs with high n-type mobility of 6cm2/V.s. For polymer composites, the objective was to obtain detailed understanding of the interactions between carbon nanotubes and the conjugated polymer; a prerequisite for using these composites in organic electronic devices. We fabricated well dispersed nanotube/polymer composites by using functionalized carbon nanotubes and studied the effect of nanotubes addition on the photophysical properties of the technologically important conjugated polymer poly(3-hexylthiophene) (P3HT). Measurement of the photoluminescence efficiency of nanotubes/polymer composites showed that addition of 10wt% carbon nanotubes effectively quenched the polymer emission indicating close electronic interactions. This indicated that nanotubes/polymer composites have potential in organic photovoltaic or light-sensing devices. Further analysis of the steady-state photoluminescence spectra revealed that nanotube addition resulted in increased structural disorder in the polymer. The incorporation of structural disorder into the polymer with the addition of even a small amount of carbon nanotubes may be detrimental to charge transport. UV-vis adsorption studies revealed that one-dimensional templating of P3HT chains by nanotubes resulted in a red-shifted feature in the solutionstate optical adsorption spectra of P3HT. This suggested that presence of nanotube surface templates the polymer self-organisation to produce highly ordered coating of P3HT chains around the nanotube. In order to elucidate the nanoscale origin of this phenomenon, we performed detailed STM studies on individual nanotubes adsorbed with P3HT chains. Since carbon nanotubes can be considered as rolled up sheets of graphite, we also performed STM on P3HT chains assembly on graphite for comparison. For P3HT assembly on HOPG, we found that while 2D crystals were observed when P3HT was cast onto HOPG from dilute solution, a thicker and more disordered film resulted when cast from concentrated solutions and subsequent layers were more likely to align normal to an underlying monolayer of P3HT on the HOPG surface. STM studies of nanotube/polymer mixtures revealed that the P3HT chains are adsorbed on nanotubes surface in such a way that the thiophene and hexyl moieties of the polymer associated with the nanotube surface in identical manner to P3HT monolayer depositions on graphite. This resulted in the increased order as inferred from adsorption UV-Vis spectroscopy, where the polymer chains, which are otherwise prone to chain kinks and twists in solution, adopt a planar configuration when adsorbed onto the nanotube surface.

A contribution of understanding the stability of commercial PLA films for food packaging and its surface modifications / Etude de la stabilité de films industriels de PLA et de leur modification de surface pour des applications en tant qu'emballage alimentaire biodégradable

Rocca Smith, Jeancarlo Renzo

13 March 2017

Les plastiques sont aujourd'hui des matériaux ubiquitaires utilisés dans tous les aspects de notre vie quotidienne, en particulier pour l'emballage alimentaire. Cependant, après usage, les plastiques sont une source de pollution de notre environnement naturel. Certains plastiques biodégradables et biosourcés sont déjà disponibles sur le marché, comme l’acide polylactique (PLA), mais ils présentent des performances inférieures. Ce travail de thèse vise à: 1) étudier la stabilité des films de PLA dans diverses conditions de température, d'humidité relative, de pH, d'exposition à des liquides ou à des vapeurs... 2) mieux comprendre l'impact de certains procédés industriels tels que les traitements corona ou pressage à chaud sur le PLA 3) combiner le PLA à des couches de gluten de blé afin de produire des complexes ayant des propriétés barrière plus élevées.Les films de PLA ont été produits par la société Taghleef Industries sur demande et avec des traitements de surface spécifiques, comme le traitement Corona. Des films et des enductions à basede gluten de blé ont été développés à l’échelle laboratoire ainsi que des complexes tricouches PLA- gluten-PLA. Les propriétés physiques et chimiques des films ont été étudiées par différentes techniques issues des sciences des matériaux et des aliments ont été utilisées, telles que l’analyse enthalpique différentielle (DSC), l'analyse thermogravimétrique (TGA), la chromatographie d'exclusion de taille (SEC), la microscopie de force atomique (AFM), la microscopie électronique (SEM), la spectroscopie infrarouge à transformée de Fourier (ATR-FTIR) et la spectroscopie de rayons X (XPS). Les propriétés fonctionnelles telles que la perméabilité à la vapeur d'eau, à l'oxygène (O2), au dioxyde de carbone (CO2) ou à l'hélium (He), la sorption de gaz et de vapeurs, les propriétés mécaniques et de surface ont également été étudiées.Exposés au CO2, les films de PLA présentent une isotherme de sorption linéaire avec l’augmentation de pression. Cependant les modifications physiques et chimiques induites à des pressions élevées n'affectent pas son utilisation dans le domaine d’application alimentaire. Au contraire, lorsque les films de PLA sont exposés à l'humidité à l'état liquide ou vapeur, leur dégradation survient après deux mois à 50 ° C (essai accéléré) suite à son hydrolyse. Cette détérioration chimique, mise en évidence par une diminution significative de la masse molaire, entraine une perte de transparence, mais également par une augmentation de la cristallinité. Par ailleurs, le pH n'affecte pas le taux d'hydrolyse, ce qui est d'un intérêt essentiel pour conditionner des aliments humides.Les films à base gluten de blé ont été choisis pour leurs propriétés de barrière élevées lorsque l’humidité relative reste faible. L'incorporation de lipides n'a pas apporté d'amélioration de leurs performances barrières. Cependant, l'utilisation d’un procédé d’homogénéisation à haute pression a permis une meilleure dispersion du gluten, ce qui a conduit à des films plus homogènes ayant ainsi de meilleures propriétés fonctionnelles. Ces conditions ont donc été retenues pour réaliser des complexes à 3 couches par assemblage d'une couche de gluten de blé entre deux couches de PLA en utilisant un pressage à chaud (10 MPa, 130 ° C, 10 min).La technologie de pressage à chaud montre une forte influence sur les films de PLA, de gluten et sur les tricouches. Elle induit une cristallisation accrue du PLA, ce qui augmente ses propriétés de barrière d'environ 40% et 60%, respectivement pour l'eau et l'oxygène. Cela masque par contre l’effet du traitement corona. D’autre part, le pressage à chaud induit une restructuration du réseau de gluten qui améliore les propriétés de barrière aux gaz des complexes, mais provoque aussi une évaporation de l'eau à l'interface gluten / PLA défavorable à l’adhésion des couches (...) / Poly(lactic acid) (PLA) is a biodegradable and renewable polyester, which is considered as the most promising eco-friendly substitute of conventional plastics. It is mainly used for food packaging applications, but some drawbacks still reduce its applications. On the one hand, its low barrier performance to gases (e.g. O2 and CO2) limits its use for applications requiring low gas transfer, such as modified atmosphere packaging (MAP) or for carbonate beverage packaging. On the other hand, its natural water sensitivity, which contributes to its biodegradation, limits its use for high moisture foods with long shelf life.Other biopolymers such as wheat gluten (WG) can be considered as interesting materials able to increase the PLA performances. WG is much more water sensitive, but it displays better gas barrier properties in dry surroundings. This complementarity in barrier performances drove us to study the development of multilayer complexes PLA-WG-PLA and to open unexplored application scenarios for these biopolymers.This project was thus intended to better understand how food components and use conditions could affect the performances of PLA films, and how these performances could be optimized by additional processing such as surface modifications (e.g. corona treatment and coatings).To that aim, three objectives were targeted:- To study the stability of industrially scale produced PLA films in contact with different molecules (CO2 and water) and in contact with vapour or liquid phases, with different pH, in order to mimic a wide range of food packaging applications.- To better understand the impact of some industrial processes such as corona or hot press treatments on PLA.- To combine PLA with WG layer to produce high barrier and biodegradable complexes.Different approaches coming from food engineering and material engineering were adopted. PLA films were produced at industrial scale by Taghleef Industries with specific surface treatments like corona. Wheat gluten films, coatings and layers were developed and optimized at lab scale as well as the 3-layers PLA-WG-PLA complexes. Different technologies able to mimic industrial processes were considered such as hot press, high pressure homogenization, ultrasounds, wet casting and spin coating. The physical and chemical properties of PLA films were then studied at the bulk and surface levels, from macroscopic to nanometer scale. The functional properties like permeability to gases (e.g. O2 and CO2) and water, gas and vapour sorption, mechanical and surface properties were also investigated.Exposed to CO2, PLA films exhibited a linear sorption behaviour with pressure, but the physical modifications induced by high pressure did not affect its use for food packaging. However, when exposed to moisture in both liquid and vapour state (i.e. environments from 50 to 100 % relative humidity (RH)), PLA was significantly degraded after two months at 50 °C (accelerated test) due to hydrolysis. This chemical deterioration was evidenced by a significant decrease of the molecular weight, which consequently induced a loss of transparency and an increase of the crystallinity. The hydrolysis was accelerated when the chemical potential of water was increased, and it was surprisingly higher for vapour compared to liquid state. In addition, pH did not affect the rate of hydrolysis.Knowing much better the limitation of PLA films, the challenge was to improve its functional properties by combining them with WG, as a high gas barrier bio-sourced and biodegradable polymer. The use of high pressure homogenization produced homogeneous WG coatings, with improved performances. This process was thus selected for making 3 layer complexes by assembly of a wheat gluten layer between two layers of PLA, together with corona treatment and hot press technologies.Corona treatment applied to PLA physically and chemically modified its surface at the nanometer scale (...) / I materiali plastici convenzionali trovano impiego in tutti campi della nostra vita, specialmente nel settore del packaging alimentare, ed in seguito all’utilizzo contaminano e danneggiano il nostro ecosistema. Materiali plastici derivanti da risorse naturali e biodegradabili, come acido polilattico (PLA), sono attualmente disponibili sul mercato anche se caratterizzati da performances inferiori.Questo progetto di dottorato è mirato 1) allo studio della stabilità di film di PLA a varie condizioni di stoccaggio come temperatura, umidità relativa, pH, o esposizione a vapori o gas; 2) a comprendere meglio le influenze di alcuni processi industriali come trattamento corona e hot press nelle proprietà dei film di PLA; 3) a sviluppare complessi multistrato tra film di PLA e di glutine che abbiano proprietà barriera più elevate rispetto ai singoli film.Gli imballaggi a base di PLA sono stati prodotti da Taghleef Industries, produttore leader nel settore e dotato di infrastrutture atte ai trattamenti di modificazione di superfice come il trattamento corona. I film a base di glutine e i coatings sono stati sviluppati e ottimizzati su scala di laboratorio, così come i complessi trilaminari PLA-glutine-PLA.Le proprietà fisiche e chimiche dei film di PLA sono state investigate a livello di superficie, così come a livello di bulk. Diverse tecniche analitiche, provenienti dal campo delle scienze dei materiali e delle scienze degli alimenti, sono state adottate in questo progetto di dottorato come calorimetria differenziale a scansione (DSC), termogravimetria (TGA), cromatografia di esclusione molecolare (SEC), microscopia a forza atomica (AFM), microscopia elettronica a scansione (SEM), spettrofotometria infrarossa a trasformata di Fourier in riflettanza totale attenuata (ATR-FTIR) e spettroscopia fotoelettronica a raggi X (XPS).Le proprietà funzionali come le permeabilità al vapore acqueo (H2O), all’ossigeno (O2), al diossido di carbonio (CO2) o all’elio (He) sono state investigate, cosi come l’assorbimento di gas e/o vapori, le proprietà meccaniche e le proprietà di superfice.Nonostante i film di PLA assorbano linearmente CO2 a pressioni crescenti, l’assorbimento di tale gas è ridotto a basse pressioni in modo da non modificare le sue proprietà fisiche – come contrariamente osservato quando il PLA è esposto a CO2 ad alte pressioni – e da non influenzare negativamente il suo utilizzo come imballaggio alimentare. Ad ogni modo, quando i film di PLA sono esposti ad ambienti umidi, o quando sono immersi in acqua liquida, sono significativamente degradati per idrolisi dopo due mesi di stoccaggio a 50 °C (test accelerato). Questo deterioramento chimico è stato evidenziato da una significativa riduzione del peso molecolare del PLA che, conseguentemente, induce una sua perdita di trasparenza e ne incrementa la sua cristallinità. Inoltre, è stato evidenziato che il pH non influenza la velocità di idrolisi. Quest’informazione ha importanza pratica per possibili utilizzi di PLA come imballaggio di alimenti ad alta umidità.Il glutine è stato scelto per le sue alte proprietà barriera, quando è protetto da ambienti ad alta umidità. Si è visto che l’incorporazione di lipidi non porta con sé grandi miglioramenti nelle performances dei film a base di glutine. Invece, l’utilizzo della tecnologia di omogeneizzazione ad alte pressioni permette una migliore dispersione del glutine, ottenendo film più omogenei e con migliori proprietà funzionali. Questa tecnologia è stata quindi scelta per produrre i complessi multistrato, intercalando i film di glutine tra due film di PLA, usando il trattamento hot press (10 MPa, 130 °C, 10 min). Si è osservato che il trattamento hot press modifica le proprietà dei film di PLA, di glutine e dei film multistrato Hot press induce cristallizzazione in PLA, e conseguentemente aumenta le sue proprietà barriera complessive, approssimativamente al 40 % all’acqua e al 60 % all’ossigeno (...) / Los materiales plásticos tradicionales son utilizados en todos los campos de nuestra vida y en particular modo como embajales de productos alimenticios; los cuales después de ser utilizados contaminan y dañan nuesto medio ambiente. Materiales plásticos derivados de recursos naturales y biodegradables, como el ácido poliláctico (PLA) se encuentran actualmente disponibles en el mercado a pesar de sus menores performances. Este proyecto de doctorado está orientado 1) al estudio de la estabilidad de películas de PLA bajo diferentes condiciones como temperatura, humedad relativa, pH o exposición a vapores o gases, 2) comprender los efectos en las propiedades de las películas de PLA de algunos procesos industriales como el tratamiento corona y hot press, 3) desarrollar complejos multicapas de PLA y gluten que tengan propiedades barrera mejores que las de las películas individuales.Los embalajes a base de PLA han sido producidos por Taghleef Industries, productor líder en el sector y dotado de las infraestructuras industriales adaptadas a los tratamientos superficiales como el tratamiento corona. Las películas de gluten y los coatings han sido desarrollados a escala de laboratorio, así como los complejos tricapa PLA-gluten-PLA.Las propiedades físicas y químicas de las películas de PLA han sido investigadas a nivel de superficie así como a nivel de bulk. Diferentes técnicas de análisis, frecuentemente utilizadas en los campos de las ciencias de los materiales y de las ciencias de los alimentos, han sido empleadas en este proyecto como calorimetría diferencial de barrido (DSC), análisis termogravimétrico (TGA), cromotagrafía de exclusión por tamaño (SEC), microscopía de fuerza atómica (AFM), microscopía electrónica de barrido (SEM), espectroscopía de infrarrojos por transformada de Fourier con reflectancia total atenuada (ATR-FTIR) y espectroscopía fotoelectrónica de rayos X (XPS).Las propiedades funcionales de los embalajes como las permeabilidades al vapor de agua, al oxígeno (O2), al dióxido de carbono (CO2) o al helio (He) han sido investigadas, asi como la absorción de gases/vapores, las propiedades mecánicas y las propiedades superficiales. A pesar de que las películas de PLA absorven linealmente CO2 a presiones mayores, la absorción del gas es reducida a bajas presiones y no modifica las propiedades físicas del PLA, como contrariamente sucede cuando el PLA es expuesto a altas presiones de CO2. Por lo tanto, su influencia en las propiedades funcionales del PLA es mínima en las normales aplicaciones alimentarias. De todos modos cuando los embalajes de PLA son expuestos a ambientes húmedos o cuando son sumergidos en agua, procesos de hidrólisis los degradan significativamente después de dos meses de conservación a 50 °C (test acelerado). Este deterioramiento químico ha sido evidenciado por una significativa reducción del peso molecular del PLA, que en consecuencia induce una pérdida de transparencia y un aumento de su cristalinidad. Además, se ha observado que el pH no influye en la velocidad de hidrólisis. Esta información tiene una importancia práctica para posibles usos del PLA como embalajes de alimentos a alta humedad. El gluten ha sido elegido por sus altas propiedades barrera cuando es protegido de ambientes a alta humedad. La incorporación de lípidos en las películas de gluten no han mejorado sus performances. Pero la tecnología de la homogenización a altas presiones ha permitido mejorar la dispersión del gluten, obteniendo películas más homogéneas y con mejores propiedades funcionales. Esta tecnología ha sido, por lo tanto, elegida para producir los complejos multicapa, intercalando las películas de gluten entre dos de PLA, utilizando el tratamiendo hot press (10 MPa, 130 °C, 10 min) (...)

Acide polylactique (PLA)

Modification de surface

Gluten de blé

Emballage multicouche

Biodégradabilité

Vieillissement accéléré

Stabilité des biopolymères

Emballage alimentaire

Film comestible

PLA

Surface modification

Wheat gluten films

Biodegradable multilayers

Biobased complexes

Laminates

Storage test

Biopolymer stability

Food packaging

Edible films

660.6

664.09

Développement et étude des propriétés des films et des pièces injectées de nano-biocomposites de nanowhiskers de cellulose et de polymères biodégradables / Processamento e estudo das propriedades de filmes e peças injetadas de nanobiocompósitos de nanocristais de celulose e matrizes biodegradáveis / Processing and study of properties of films and injected pieces of nanobiocomposites of cellulose whiskers and biodegradable polymers

Morelli, Carolina Lipparelli

04 April 2014

Notre travail a pour objectif l'étude de l'influence de l'ajout de nanocristaux de cellulose dans des matrices biodégradables sur leurs propriétés. Des films composites et des pièces injectées ont été préparés et caractérisés. Dans ce but, ont été choisis comme matrices le poly(acide lactique), PLA, et le poly (butylène adipate-co-téréphtalate)), PBAT. Deux matières première d'où des nanocristaux de celulose ont été extraites ont été sélectionnées : le bois balse et la cellulose microcrystalline (CMC). En raison du caractère fortement polaire des nanocristaux de cellulose différentes voies de modifications chimiques de la surface de ces particules ont été testées afin d'assurer une bonne dispersion de ceux-ci lorsqu'ils sont ajoutés à des matrices polymères de polarité inférieure. En effet, les approches testées étaient: (a) le greffage de deux types d'isocyanates, dont l'un aliphatique et l'autre aromatique: l'octadécyl isocyanate (NCC_oct) et le phényl-butyle isocyanate (NCC_fb), respectivement; (b) le greffage de poly(butylène glutarate) à travers la technique de polymérisation in situ (NCC_PBG); (c) le greffage de l'acide polyacrylique à travers la technique appelée click chemistry (NCC_PA); et (d) la silanisation avec le - methacryloxy-propyle-trimethoxy-silane(NCC_MPS). Les NCCs initiaux et modifiés ont été ajoutés aux matrices de PBAT ou du PLA par procédés de mélanges à partir de solution (casting) ou à partir de l'état fondu (par extrusion ou en utilisent un homogénisateur de type Drais). En général, la modification chimique de la surface de NCC a augmenté la résistance thermique de celui-ci, a diminué son caractère hydrophile et a amélioré la dispersion des NCCs dans les matrices de PLA et PBAT. Cela a provoqué des augmentations encore plus grandes dans les propriétés de ces polymères, en fonction du type de modification et du procédé de fabrication utilisé. La caractérisation des nanocomposites a démontré que, en général, l'addition des NCCs a augmenté le module d'élasticité de la matrice et a conservé sa rigidité même à températures relativement élevées. Des niveaux plus élevés de NCC conduisent à de plus grandes augmentations de la rigidité. La perméabilité à la vapeur d'eau de PBAT a été réduite par l'introduction de NCC et n'a pas changé dans le cas du PLA. Les résullts de ces travaux ont indiqué de bonnes perspectives concernant l'utilisation des nanocristaux de cellulose comme élément de renfort de matrices polymères. De manière générale, le présent travail a démontré que les NCCs étaient capables d'améliorer les propriétés mécaniques, thermiques et de barrières du PBAT et du PLA, qui sont deux polymères biodégradables largement utilisés dans les applications de films ou de pièces plastiques. De plus, les résultats montrent qu'il est possible de modifier la polarité des NCC en les soumettant à des modifications chimiques de surface afin d'éviter leur agglomération par la formation de ponts de liaisons hydrogènes et de les rendre compatibles avec différentes matrices polymères. Ces modifications chimiques tendent aussi à élever la résistance thermique des NCCs. De cette manière, les procédés à l'échelle industrielle comme l'extrusion et l'injection peuvent être utilisés et fournissent de bons résultats. / This study aimed at evaluating the potential of application of cellulose nanocrystals as reinforcing elements of biodegradable polymeric matrices, in the films and injection molded pieces applications. Two polymeric matrices with different properties were used, namely: poly(butylene adipate-co-terephthalate), PBAT, and poly(lactic acid), PLA. For the extraction of cellulose nanocrystals (NCC), two sources were selected: microcrystalline cellulose (CMC) and balsa wood . Due to the high polarity of cellulose nanocrystals, different approaches of surface chemical modifications of these particles were tested, in order to ensure their good dispersion when added to polymeric matrices of lower polarity. They were: a) chemical modification with two types of isocyanates, an aliphatic one (octadecyl isocyanate) and an aromatic one (phenylbutyl isocyanate); b) grafting of poly (butylene glutarate) using the in situ polymerization technique; c) silanization treatment; and d) grafting of poly(acrylic acid) through click chemistry technique. Modified and unmodified NCCs were processed with PBAT and PLA by casting or melt extrusion processing techniques. In general, the chemical modification of NCC surface increased their thermal resistance, decreased their polarity and improved their dispersion into PLA and PBAT matrices. Some of these treatments, as well as the processing conditions enabled an increase in the overall mechanical properties of the polymers. Thus, the characterization of the nanocomposites showed that NCC addition increased the elastic modulus of the matrix and retained its higher stiffness even under relatively high temperatures. Higher NCC contents led to larger increases in the stiffness of the ensuing composites. The water vapor permeability of PBAT was also reduced with the introduction of NCC. This work points out several potential good perspectives for the use of celulose nanocrystals as reinforcing elements of polymeric matrices. It showed also that it is possible to obtain significant improvements in the polymer properties using the same processing techniques as those used at industrial scale, such as melt extrusion and injection molding. / O presente estudo de doutorado teve como objetivo avaliar o potencial deaplicação de nanocristais de celulose como reforço em matrizes poliméricasbiodegradáveis, em aplicações de filmes ou em peças moldadas por injeção.Duas matrizes poliméricas de diferentes propriedades foram utilizadas paraestudo nessas aplicações, sendo elas: poli(butileno adipato-co-tereftalato),PBAT, e poli(ácido láctico), PLA. Foram também selecionadas duas fontes paraextração dos nanocristais de celulose (NCC): a celulose microcristalina (CMC)e a madeira balsa.Devido ao caráter altamente polar dos nanocristais de celulose diferentesrotas de modificações químicas superficiais dessas partículas foram testadas,visando garantir a boa dispersão dos mesmos quando adicionados às matrizespoliméricas de menor polaridade. Foram elas: a) modificação química com doistipos de isocianatos, sendo um de cadeia alifática (octadecil isocianato) e outrode cadeia aromática (fenilbutil isocianato); b) enxertia do poli(butileno glutarato)através da técnica de polimerização in situ; c) tratamento de silanização com -metacriloxi-propil-trimetoxi-silano; d) enxertia de poli(ácido acrílico) através datécnica de click chemistry.NCC modificados e não modificados foram processados com PBAT ouPLA através de mistura com o polímero em solução (casting) ou no estadofundido (extrusão ou homogeneizador de alta rotação do tipo Drais).De modo geral, modificações químicas superficiais dos NCC aumentarama estabilidade térmica dos mesmos, diminuíram sua polaridade e melhoraram adispersão dos NCC nas matrizes de PBAT ou PLA. Isso fez com queincrementos ainda maiores nas propriedades desses polímeros pudessem serxxivalcançados, dependendo do tipo de modificação e do processo de misturautilizados.A caracterização dos nanocompósitos obtidos mostrou que a adição deNCC elevou o módulo elástico das matrizes e conservou sua maior rigidezmesmo em temperaturas relativamente elevadas, sendo que maiores teores deNCC levaram a maiores aumentos na rigidez. A permeabilidade a vapor deágua do PBAT também foi reduzida com a introdução dos NCC e não foialterada no caso do PLA.Os resultados desse trabalho apontaram boas perspectivas no uso dosnanocristais de celulose como reforços de matrizes poliméricas. Tambémmostraram que é possível obter melhorias nas propriedades de polímerosmesmo através da utilização de processos de maior reprodutibilidade emescala industrial, como extrusão e injeção.

Nanocristaux de cellulose

Polymères biodégradables

Modification chimique de surface

Extrusion

Nanocomposites

Percolation

Celulose nanocrystals

Biodegradable polymers

Nanocomposites

Chemical surface modification

Extrusion

Percolation

Nanocristais de celulose

Polímeros biodegradáveis

Nanocompósitos

Modificação química superficial

Extrusão

Moldagem por injeção

Percolação

620

Processamento e estudo das propriedades de filmes e peças injetadas de nanobiocompósitos de nanocristais de celulose e matrizes biodegradáveis

Morelli, Carolina Lipparelli

04 April 2014

Made available in DSpace on 2016-06-02T19:10:22Z (GMT). No. of bitstreams: 1 6015.pdf: 4561575 bytes, checksum: 252a378ed3b63f6b097f991565a256f1 (MD5) Previous issue date: 2014-04-04 / Financiadora de Estudos e Projetos / This study aimed at evaluating the potential of application of cellulose nanocrystals as reinforcing elements of biodegradable polymeric matrices, in the films and injection molded pieces applications. Two polymeric matrices with different properties were used, namely: poly(butylene adipate-co-terephthalate), PBAT, and poly(lactic acid), PLA. For the extraction of cellulose nanocrystals (NCC), two sources were selected: microcrystalline cellulose (CMC) and balsa wood . Due to the high polarity of cellulose nanocrystals, different approaches of surface chemical modifications of these particles were tested, in order to ensure their good dispersion when added to polymeric matrices of lower polarity. They were: a) chemical modification with two types of isocyanates, an aliphatic one (octadecyl isocyanate) and an aromatic one (phenylbutyl isocyanate); b) grafting of poly (butylene glutarate) using the in situ polymerization technique; c) silanization treatment; and d) grafting of poly(acrylic acid) through click chemistry technique. Modified and unmodified NCCs were processed with PBAT and PLA by casting or melt extrusion processing techniques. In general, the chemical modification of NCC surface increased their thermal resistance, decreased their polarity and improved their dispersion into PLA and PBAT matrices. Some of these treatments, as well as the processing conditions enabled an increase in the overall mechanical properties of the polymers. Thus, the characterization of the nanocomposites showed that NCC addition increased the elastic modulus of the matrix and retained its higher stiffness even under relatively high temperatures. Higher NCC contents led to larger increases in the stiffness of the ensuing composites. The water vapor permeability of PBAT was also reduced with the introduction of NCC. This work points out several potential good perspectives for the use of celulose nanocrystals as reinforcing elements of polymeric matrices. It showed also that it is possible to obtain significant improvements in the polymer properties using the same processing techniques as those used at industrial scale, such as melt extrusion and injection molding. / O presente estudo de doutorado teve como objetivo avaliar o potencial de aplicação de nanocristais de celulose como reforço em matrizes poliméricas biodegradáveis, em aplicações de filmes ou em peças moldadas por injeção. Duas matrizes poliméricas de diferentes propriedades foram utilizadas para estudo nessas aplicações, sendo elas: poli(butileno adipato-co-tereftalato), PBAT, e poli(ácido láctico), PLA. Foram também selecionadas duas fontes para extração dos nanocristais de celulose (NCC): a celulose microcristalina (CMC) e a madeira balsa. Devido ao caráter altamente polar dos nanocristais de celulose diferentes rotas de modificações químicas superficiais dessas partículas foram testadas, visando garantir a boa dispersão dos mesmos quando adicionados às matrizes poliméricas de menor polaridade. Foram elas: a) modificação química com dois tipos de isocianatos, sendo um de cadeia alifática (octadecil isocianato) e outro de cadeia aromática (fenilbutil isocianato); b) enxertia do poli(butileno glutarato) através da técnica de polimerização in situ; c) tratamento de silanização com &#61543;- metacriloxi-propil-trimetoxi-silano; d) enxertia de poli(ácido acrílico) através da técnica de click chemistry. NCC modificados e não modificados foram processados com PBAT ou PLA através de mistura com o polímero em solução (casting) ou no estado fundido (extrusão ou homogeneizador de alta rotação do tipo Drais). De modo geral, modificações químicas superficiais dos NCC aumentaram a estabilidade térmica dos mesmos, diminuíram sua polaridade e melhoraram a dispersão dos NCC nas matrizes de PBAT ou PLA. Isso fez com que incrementos ainda maiores nas propriedades desses polímeros pudessem ser alcançados, dependendo do tipo de modificação e do processo de mistura utilizados. A caracterização dos nanocompósitos obtidos mostrou que a adição de NCC elevou o módulo elástico das matrizes e conservou sua maior rigidez mesmo em temperaturas relativamente elevadas, sendo que maiores teores de NCC levaram a maiores aumentos na rigidez. A permeabilidade a vapor de água do PBAT também foi reduzida com a introdução dos NCC e não foi alterada no caso do PLA. Os resultados desse trabalho apontaram boas perspectivas no uso dos nanocristais de celulose como reforços de matrizes poliméricas. Também mostraram que é possível obter melhorias nas propriedades de polímeros mesmo através da utilização de processos de maior reprodutibilidade em escala industrial, como extrusão e injeção.

Polímeros

Nanocristais de celulose

Polímeros biodegradáveis

Nanocompósitos

Modificação química superficial

Processo de extrusão

Moldagem por injeção

Percolação

Celulose nanocrystals

Biodegradable polymers

Nanocomposites

Chemical surface modification

Extrusion

Injection molding

Percolation

Caracterização da alumina anódica porosa modificada por plasma / Characterization of alumina porous anodic modified by plasma

Silva, Karina Rodrigues da

29 June 2015

Submitted by Milena Rubi (milenarubi@ufscar.br) on 2016-11-17T17:43:21Z No. of bitstreams: 1 RODRIGUES_Karina_2015.pdf: 7918406 bytes, checksum: 5c7eded70cc8a9dd00ce5c1b2d70d846 (MD5) / Approved for entry into archive by Milena Rubi (milenarubi@ufscar.br) on 2016-11-17T17:43:31Z (GMT) No. of bitstreams: 1 RODRIGUES_Karina_2015.pdf: 7918406 bytes, checksum: 5c7eded70cc8a9dd00ce5c1b2d70d846 (MD5) / Approved for entry into archive by Milena Rubi (milenarubi@ufscar.br) on 2016-11-17T17:43:39Z (GMT) No. of bitstreams: 1 RODRIGUES_Karina_2015.pdf: 7918406 bytes, checksum: 5c7eded70cc8a9dd00ce5c1b2d70d846 (MD5) / Made available in DSpace on 2016-11-17T17:43:54Z (GMT). No. of bitstreams: 1 RODRIGUES_Karina_2015.pdf: 7918406 bytes, checksum: 5c7eded70cc8a9dd00ce5c1b2d70d846 (MD5) Previous issue date: 2015-06-29 / Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES) / In this study, the wettability of porous anodic alumina (PAA) surfaces modified by plasma was investigated. The porous anodic alumina films were grown on aluminum substrate using a two step anodization procedure in oxalic acid solution under potentiostatic regime. The surfaces of PAA films were modified by plasma treatment or plasma deposition techniques. Prior to surface modification, the impurities were removed by a plasma cleaning procedure. Oxygen was used in plasma treatment in order to produce hydrophilic surfaces. On the other hand, the plasma deposition (in HMDSO or HMDSO + argon mixture) was performed to produce hydrophobic surfaces or less hydrophilic surface. Electropolished aluminum without PAA film were used as reference. The influence of substrate morphology on wettability was analyzed. The morphological characterization was performed by scanning electron microscopy (SEM). The microstructural analysis was carried out using Fourier Transformed Infrared Spectroscopy (FTIR). A goniometer was used to measure the contact angle and evaluate the wettability of electroplished aluminum and PAA films. The results showed that the wettability of the samples was affect by chemical interactions of functional groups on the surface deposited after plasma treatment. The effect of the porous surface morphology on wettability was not significant compared to the plasma treated films with new chemical interactions effects. / Neste trabalho foram investigadas as propriedades de molhabilidade das superfícies nanoestruturadas da alumina anódica porosa (AAP) modificadas por plasma. Os filmes de AAP foram produzidos sobre substrato de alumínio pelo método de anodização potenciostática em duas etapas em solução de ácido oxálico. Após a fabricação, as amostras foram submetidas a um tratamento a plasma (com oxigênio) ou a deposição a plasma (em HMDSO ou em uma mistura de HMDSO e argônio). Antes das modificações das superfícies, removeram-se as impurezas das amostras através de técnicas de limpeza a plasma. No tratamento a plasma, o gás oxigênio foi utilizado para a obtenção de superfícies hidrofílicas. Por outro lado, para tornar a superfície hidrofóbica ou menos hidrofílica, foram feitas duas séries de deposição a plasma, uma contendo uma mistura de argônio e HMDSO e outra série somente com HMDSO. O tratamento ou deposição a plasma também foram feitas em amostras de alumínio eletropolido, sem a camada de AAP, a fim de verificar a influência morfológica do substrato na molhabilidade. A caracterização morfológica dos filmes de AAP foi feita por microscopia eletrônica de varredura (MEV), onde foi verificada a formação dos poros na superfície. A caracterização microestrutural foi feita por espectroscopia de absorção no infravermelho por transformada de Fourier (FTIR) com o objetivo de verificar as alterações químicas na superfície. A molhabilidade foi analisada utilizando um goniômetro, equipamento que realiza medição direta do ângulo de contato. Os resultados mostram que a molhabilidade da superfície é afetada por interações químicas dos grupos funcionais na superfície dos filmes. Por outro lado, o efeito da morfologia sobre a molhabilidade da superfície não é significativo nas condições estudadas.

Modificação por plasma

Molhabilidade

Ângulo de contato

Plasma

Alumina anódica porosa (AAP)

Óxido de alumínio

Materiais nanoestruturados

Materiais nanoestruturados

Porous Anodic Alumina (PAA)

Surface modification

Wettability

Contact angle

Plasma treatment

Aluminum oxide

Nanostructured materials

OUTROS

Desenho e Constru??o de um prot?tipo gerador de jato de plasma frio a press?o atmosf?rica para aplica??es biom?dicas

Nascimento Neto, Arlindo Balbino do

07 February 2014

Made available in DSpace on 2014-12-17T14:58:24Z (GMT). No. of bitstreams: 1 ArlindoBNN_DISSERT.pdf: 2586996 bytes, checksum: 478bf85288aae614a5921757e3272558 (MD5) Previous issue date: 2014-02-07 / Conselho Nacional de Desenvolvimento Cient?fico e Tecnol?gico / Research for better performance materials in biomedical applications are constants. Thus recent studies aimed at the development of new techniques for modification of surfaces. The low pressure plasma has been highlighted for its versatility and for being environmentally friendly, achieving good results in the modification of physic chemical properties of materials. However, it is requires an expensive vacuum system and cannot able to generate superficial changes in specific regions. Furthermore, it is limits their use in polymeric materials and sensitive terms due to high process temperatures. Therefore, new techniques capable of generating cold plasma at atmospheric pressure (APPJ) were created. In order to perform surface treatments on biomaterials in specific regions was built a prototype capable of generating a cold plasma jet. The prototype plasma generator consists of a high voltage source, a support arm, sample port and a nozzle through which the ionized argon. The device was formed to a dielectric tube and two electrodes. This work was varied some parameters such as position between electrodes, voltage and electrical frequency to verify the behavior of glow discharges. The disc of titanium was polished and there was a surface modification. The power consumed, length, intensity and surface modifications of titanium were analyzed. The energy consumed during the discharges was observed by the Lissajous figure method. To check the length of the jets was realized with Image Pro Plus software. The modifications of the titanium surfaces were observed by optical microscopy (OM ) and atomic force microscopy (AFM ). The study showed that variations of the parameters such as voltage, frequency and geometric position between the electrodes influence the formation of the plasma jet. It was concluded that the plasma jet near room temperature and atmospheric pressure was able to cause modifications in titanium surface / Pesquisas na busca por materiais com melhor desempenho para aplica??es biom?dicas s?o constantes. Assim, estudos recentes buscam o desenvolvimento de novas t?cnicas para modifica??es de superf?cies. O plasma a baixa press?o vem se destacando pela sua versatilidade e por ser ambientalmente correto, obtendo-se bons resultados na modifica??o das propriedades f?sico-qu?micas dos materiais. Por?m, esta t?cnica necessita de um sistema de v?cuo de alto custo e n?o ? capaz de gerar modifica??es superficiais em regi?es pontuais. Al?m disso, limita seu uso em materiais polim?ricos e termosens?veis, devido ?s altas temperaturas do processo. Diante disso, foram criadas novas t?cnicas capazes de gerar um plasma frio a press?o atmosf?rica (APPJ). Com o objetivo de realizar tratamentos superficiais em biomateriais em regi?es pontuais, foi constru?do um prot?tipo capaz de gerar um jato de plasma frio. O prot?tipo gerador de plasma consiste em uma fonte de alta tens?o, um bra?o suporte, um porta amostra e uma ponteira por onde passa o arg?nio ionizado. Dentro desta ponteira existe um tubo diel?trico e dois eletrodos. Neste estudo foram variados alguns par?metros como: posi??o entre eletrodos, tens?o e frequ?ncia el?trica para verificar o comportamento das descargas luminescentes. Tratou-se disco de tit?nio grau II polido e verificou-se a energia el?trica consumida, comprimento, intensidade e modifica??es superficiais do tit?nio. A energia consumida durante as descargas foram verificadas pelo m?todo da figura de Lissajous. Para verificar o comprimento dos jatos foi utilizado o software Image Pro Plus. As modifica??es na superf?cie do tit?nio foram verificadas por microscopia ?tica (MO) e de for?a at?mica (MFA). O trabalho mostrou que varia??es dos par?metros de tens?o, frequ?ncia e posi??o geom?trica entre os eletrodos influenciam na forma??o do jato de plasma. Foi poss?vel concluirque o jato de plasma pr?ximo ? temperatura ambiente e a press?o atmosf?rica foi capaz de provocar modifica??es superficiais no tit?nio

CNPQ::ENGENHARIAS::ENGENHARIA MECANICA

Design of mechanoresponsive surfaces and materials / Conception des surfaces et des matériaux mécano-répondants

Rios Neyra, César

26 September 2013

Le but de ma thèse a été de concevoir des matériaux chimio-mécano répondants, des matériaux capables de permettre une transformation chimique réversible lorsqu’ils sont soumis à un stress mécanique. Tous les systèmes conçus ont été développés sur des substrats en silicone. Une première approche a consisté à créer des surfaces à sites cryptiques où une biotine est enfouie dans des brosses de chaines de poly(éthylène glycol). Le système streptavidine/biotine a été utilisé comme modèle. Ces surfaces sont anti-adsorbantes à la streptavidine sauf lorsqu’elles sont étirées à 50% où la biotine est reconnue mais les surfaces sont non réversibles. Dans une seconde approche, nous avons modifiés la surface du silicone par adsorption d’une multicouche de polyélectrolytes. Cette stratégie est basée sur la réticulation covalente du film par l’enzyme β-galactosidase modifiée. Nous sommes ainsi parvenus à créer une surface présentant une activité catalytique modulable par l’étirement mécanique, et ce, d’une façon partiellement réversible. Ce travail représente le premier exemple d’un système où une contrainte mécanique imposée à un matériau permet la déformation conformationnelle d’une enzyme et ainsi la diminution de l’activité catalytique. Dans une dernière approche, nous avons conçu un système mixte composé d’un substrat de silicone sur lequel un gel de polyacrylamide est greffée de façon covalente. Des enzymes ou des mécanophores pourront ainsi être inclus dans le réseau polymérique du gel de polyacrylamide et être étirés. Nous sommes parvenus à préparer de tels systèmes où l’hydrogel reste solidaire du film de silicone, sans apparition de craquelures jusqu’à 50%d’étirement. / The goal of my PhD was to develop new routes to design chemo-mechanoresponsive materials, materials that respond chemically to a mechanical stress, in a reversible way. All the systems designed during my PhD thesis were based on the functionalization of silicone sheets. First we created cryptic site surfaces by embedding biotin ligands into PEG brushes. The couple streptavidin/biotin was used as a model system. At rest, the surface so-prepared was antifouling and biotin ligands were specifically recognized by the streptavidin when the surface was stretched at 50%. Unfortunately, in this first approach, the mechanosensitive surface did not lead to a reversible process. In a second approach, we modified the silicone surface by using the polyelectrolyte multilayer (PEM) film deposition. This strategy was based on the covalent cross-linking of modified enzyme, the β-galactosidase, into the PEM. We succeeded in modulating the enzyme activity in the film under stretching and this approach appears as partially reversible under stretching/unstretching cycles. This work represents the first reported system where enzymatic activity can be modulated by stretching due to modulation of the enzyme conformation. In a last approach, we also designed a mixed system consisting of a silicone sheet onto which a polyacrylamide hydrogel is covalentlyattached with the goal to create a stretchable gel into which one can covalently attach enzymes or chemical mechanophores. These enzymes or mechanophores can thus be put under mechanical stress. We succeeded in creating a system that can be stretched up to 50% without detachment of the gel from the silicone and without inducing cracks in the gel.

Matériaux chimio-mécano répondants

Traitement de surface

Polydiméthylsiloxane

Multicouches de polyélectrolytes

Biocatalyse contrôlée

Hydrogels de polyacrylamides

Polymérisation

Matériaux mous

Chemo-mechanoresponsive materials

Surface modification

Polydimethylsiloxane

Polyelectrolyte multilayers

Biocatalysis control

Polyacrylamide hydrogels

Polymerization

Soft matter

531.3

660.29

620.19

Structure of prion β-oligomers as determined by structural proteomics

Serpa, Jason John

07 September 2017

The conversion of the native monomeric cellular prion protein (PrPC) into an aggregated pathological β-oligomeric (PrPβ) and an infectious form (PrPSc) is the central element in the development of prion diseases. The structure of the aggregates and the molecular mechanisms of the conformational change involved in this conversion are still unknown. My research hypothesis was that a specific structural rearrangement of normal PrPC monomers leads to the formation of new inter-subunit interaction interfaces in the prion aggregates, leading to aggregation. My approach was to use constraints obtained by structural proteomic methods to create a 3D model of urea-acid induced recombinant prion oligomers (PrPβ). My hypothesis was that this model would explain the mechanism of the conformational change involved in the conversion, the early formation of the β-structure nucleation site, and would describe the mode of assembly of the subunits within the oligomer. I applied a combination of limited proteolysis, surface modification, chemical crosslinking and hydrogen/deuterium exchange (HDX) with mass spectrometry for the differential characterization of the native and the urea-acid converted prion β-oligomer structures to get an insight into the mechanism of the conversion and aggregation. Using HDX, I detected a region of the protein in which backbone amides become more protected from exchange in PrPβ compared to PrPC. In order to obtain the inter-residue distance constraints to guide the assembly of the oligomer model, I then applied zero-length and short-range crosslinking to an equimolar mixture of 14N/15N-metabolically labeled β-oligomer thereby enabling the classification of the crosslinks as either intra-protein or inter-protein. Working with the Dokholyan group at the University of North Carolina at Chapel Hill, I was able to assemble a structure of the β-oligomer based on the combination of constraints obtained from all methods. By comparing the structures before and after the conversion, I was able to deduce the conformational change, that occurs during the conversion as the rearrangement and disassembly of the beta sheet 1– helix 1 – beta sheet 2 (β1-H1-β2) region from the helix 2 – helix 3 (H2-H3) core, forming new β-sheet nucleation site and resulting in the exposure of hydrophobic residues patches leading to formation of inter-protein contacts within aggregates. / Graduate / 2018-06-14

β-oligomer

prion

PrP

HDX

hydrogen/deuterium exchange

crosslinking

mass spectrometry

limited proteolysis

surface modification

protein structure

proteomics

structural proteomics

prion structure

discrete molecular dynamics

CL-DMD

misfolding

aggregation

Advanced low temperature metal hydride materials for low temperature proton exchange membrane fuel cell application

Ntsendwana, Bulelwa

January 2010

Magister Scientiae - MSc / Energy is one of the basic needs of human beings and is extremely crucial for continued development of human life. Our work, leisure and our economic, social and physical welfare all depend on the sufficient, uninterrupted supply of energy. Therefore, it is essential to provide adequate and affordable energy for improving human welfare and raising living standards. Global concern over environmental climate change linked to fossil fuel consumption has increased pressure to generate power from renewable sources [1]. Although substantial advances in renewable energy technologies have been made, significant challenges remain in developing integrated renewable energy systems due primarily to mismatch between load demand and source capabilities [2]. The output from renewable energy sources such as photo-voltaic, wind, tidal, and micro-hydro fluctuate on an hourly, daily, and seasonal basis. As a result, these devices are not well suited for directly powering loads that require a uniform and uninterrupted supply of input energy. / South Africa

Hydrogen energy

Polymer Exchange Membrane Fuel Cell

Solid state hydrogen storage

Metal hydrides

AB5 hydride-forming alloy

Ce-substituted LaNi5

Surface modification

Kinetics

Thermodynamics

Pressure-Composition Isotherm

Thermal conductivity

Heat and Mass transfer