Anisotropic Morphologies and Properties in Perfluorosulfonate Ionomer-Based Materials

Park, Jong Keun

24 January 2010

The overall goal of this investigation was to elucidate specific structure-property relationships in perfluorosulfonate ionomers (PFSIs)-related materials. The project can be broken into two primary foci. First, we explored the current state of understanding related to morphology-property relationships in PFSIs with specific attention to the nano-scale organization of the ionic and crystalline domains. Specifically, the effect of uniaxial orientation on the structure and transport properties of Nafion® membranes was examined. Small angle X-ray scattering (SAXS) experiments on dry membranes that were uniaxially elongated showed a strong anisotropic morphology which was shown to persist over the swelling process without a significant relaxation. Herman's order parameters for the ionomer peak were strongly influenced by uniaxial deformation, which supports the presence of cylindrical rather than spherical morphology for ionic domains. Comparison of the water diffusion coefficients between unoriented and oriented samples revealed that uniaxial deformation of Nafion® membranes essentially enhances transport ability in one direction (i.e., the parallel to draw direction) and suppresses in the other two directions (i.e., two orthogonal directions relative to the stretching direction). Based on 1-dimensional analyses of oriented SAXS patterns at the azimuthal angle 90o, three recent models (lamellar model, semicrystalline rod-like model and fringed-micelle model) for the morphology of PFSIs were critically evaluated. The loss of meridional scattering, different orientation behavior of the crystalline and ionic domains, and inherent chain stiffness precludes the possibility of a chain-folded lamellar morphology. While the inter-aggregate dimensions remain constant at high draw ratios, the inter-crystalline spacings decrease significantly. Coupled with the distinctly different orientation behavior, these observations preclude the existence of crystallites solely within rod-like aggregates. While the worm-like ionic channel model was able to explain the behavior of SAXS and wide angle X-ray scattering (WAXS) relatively well, this model also had limitations such as (1) crystalline domains directly linked to the ionic domain (and thus a lack of amorphous domains) and (2) a presence of only a single ionic channel between two neighboring crystallites. Second, electroactive materials, specifically ionic polymer-metal composites (IPMCs) that undergo bending motions with the stimulus of a relatively weak electric field were fabricated. To understand the role of the nanoscale morphology of the membrane matrix in affecting the actuation behavior of IPMC systems, we evaluated actuation performance of IPMCs subjected to uniaxial orientation. The PFSI nanostructure altered by uniaxial orientation mimicked the fibrillar structure of biological muscle tissue and yielded a new anisotropic actuation response. It was evident that IPMCs cut from films oriented perpendicular to the draw direction yielded displacement values that were significantly greater than that of unoriented IPMCs. In contrast, IPMCs cut from films oriented parallel to the draw direction appeared to resist bending and yield displacement values that were much less than that of the unoriented IPMC. This anisotropic actuation behavior was attributed to the contribution of the nanoscale morphology to the bulk bending modulus. Overall, this study clearly demonstrated, for the first time, the importance of the nanoscale morphology in affecting/controlling the actuation behavior in IPMC systems. / Ph. D.

orientation

crystallinity

uniaxial stretching

electroactive polymer

ionic polymer-metal composite (IPMC)

proton exchange membrane

anisotropic morphology

Nafion

perfluorosulfonate ionomers

Synthesis and Properties of Ion-Containing Block and Segmented Copolymers and Their Composites

Gao, Renlong

13 April 2012

Ion-containing segmented polyurethanes exhibit unique morphology and physical properties due to synergistic interactions of electrostatic, hydrogen bonding, and hydrophobic interactions. A fundamental investigation on a series of well-defined ion-containing polyurethanes elucidated the influence of charge placement, charge density, and soft segment structure on physical properties, hydrogen bonding, and morphologies. An unprecedented comparison of poly(ethylene oxide)(PEO)-based sulfonated polyurethanes containing sulfonate anions either in the soft segments or hard segments revealed that sulfonate charge placement dramatically influenced microphase separation and physical properties of segmented polyurethanes, due to altered hydrogen bonding and thermodynamic immiscibility between soft and hard segments. Moreover, studies on sulfonated polyurethanes with identical sulfonated hard segments but different soft segment structures indicated that soft segment structure tailored sulfonated polyurethanes for a wide range of mechanical properties. Sulfonated polyurethanes incorporated with ammonium-functionalized multi-walled carbon nanotubes (MWCNTs) generated novel polyurethane nanocomposites with significantly enhanced mechanical performance. Modification of MWCNTs followed a dendritic strategy, which doubled the functionality by incorporating two ammonium cations per acid site. Complementary characterization demonstrated successful covalent functionalization and formation of surface-bound ammonium salts. Upon comparison with pristine MWCNTs, ammonium-functionalized MWCNTs exhibited significantly enhanced dispersibility in both DMF and sulfonated polyurethane matrices due to good solvation of ammonium cations and intermolecular ionic interactions between anionic polyurethanes and cationic MWCNTs. Segmented polyurethanes containing sulfonated PEO-based soft segments and nonionic hard segments were incorporated with various contents of room temperature ionic liquid, 1-ethyl-3-methylimidazolium ethylsulfate (EMIm ES), to investigate the influence of ionic liquid on physical properties, morphologies, and ionic conductivity. Results indicated that EMIm ES preferentially located in the sulfonated PEO soft phase, leading to significantly enhanced ionic conductivity and well-maintained mechanical properties. These properties are highly desirable for electromechanical transducer applications. Electromechanical actuators fabricated with sulfonated polyurethane/IL composite membranes exhibited effective response under a low applied voltage (4 V). However, in the case of an imidazolium-containing segmented polyurethane with imidazolium ionic hard segments and hydrophobic poly(tetramethylene oxide) (PTMO) soft segments, EMIm ES selectively located into the imidazolium ionic hard domains, as evidenced with a constant PTMO soft segment glass transition temperature (Tg) and systematically reduced imidazolium hard segment Tg. Dielectric relaxation spectroscopy demonstrated that ionic conductivity of imidazolium-containing segmented polyurethanes increased by five orders of magnitude upon incorporation of 30 wt% EMIm ES. Imidazolium-containing sulfonated pentablock copolymers were also investigated to elucidate the influence of imidazolium counter cation structures on solution rheology, morphology, and thermal and mechanical properties. Combination of living anionic polymerization and post functionalization strategies provided well-defined sulfonated pentablock copolymers containing structured imidazolium cations in sulfonated polystyrene middle block. Varying alkyl substitute length on imidazolium cations tailored physical properties and morphologies of sulfonated pentablock copolymers. Results indicated that long alkyl substitutes (octyl and dodecyl) on imidazolium cations significantly influenced solution rheological behavior, morphology, and water uptake properties of sulfonated pentablock copolymers due to the altered characteristic of imidazolium cations. Imidazolium-containing sulfonated pentablock copolymers exhibited systematically tailored mechanical properties due to the plasticizing effect of alkyl substitutes. In addition, incorporation of ionic liquids into sulfonated pentablock copolymers further tailored their mechanical properties and ionic conductivity, which made these materials suitable for electromechanical transducer applications. All sulfonated pentablock copolymers were successfully fabricated into actuator devices, which exhibited effective actuation under a low applied voltage (4 V). / Ph. D.

step-growth polymerization

multi-walled carbon nanotubes

sulfonated block copolymers

sulfonated polyurethane

nanocomposites

ionic liquids

electroactive actuator

The Application of Thin Film Ionic Self-assembled Multilayer (ISAM) Nanostructures in Electromechanical Bending Actuators and Micro-fabricated Gas Chromatography (uGC) Devices

Wang, Dong

14 January 2015

Ionic self-assembled multilayer (ISAM) thin film nanostructures, including highly porous and conductive gold nanoparticles (GNP), and highly porous and thermally stable silica nanoparticles (SNP), were fabricated via the layer-by-layer (LbL) self-assembly technique. Their application in ionic polymer-metal composite (IPMC) electromechanical bending actuators and microfabricated gas chromatography (microGC) devices were investigated and significant performance improvements of these devices were achieved. IPMC bending actuators, consisting of an ionic electroactive polymer (iEAP) membrane as backbone, ionic liquids (IL) as electrolyte, and ISAM GNP thin film as porous electrode, were fabricated and investigated. The influences of humidity, conductive network composite (CNC), and IL uptake on the bending performance were examined and discussed. An equivalent circuit model to simulate both the electrical and mechanical responses was also proposed and experimentally verified. Moreover, IPMC actuators made from other newly synthesized iEAP membranes were fabricated and tested. Some of them showed promising performance that was comparable or even better as compared to the ones made from Nafion. LbL fabricated ISAM SNPs thin film coatings were also applied in the microGC devices including micro fabricated thermal preconcentrators (microTPC) and separation columns (microSC) as adsorbent and stationary phase materials, respectively. New fabrication approaches were developed to selectively coat uniform conformal ISAM SNP coatings in these devices with different 3D microstructures. Thus, functionalized microTPCs and microSCs showed good performance, which can be further improved by using the ISAM SNPs coating as a nanotemplate for modifying additional polymer adsorbents or as the anchor sites for incorporating functional molecules for targeting detection. / Ph. D.

Ionic Self-Assembled Multilayers

Ionic Electroactive Polymeric Actuators

Interfaces moleculares baseadas em nanocompósitos de VXG com espécies polimetaladas / Molecular-based interfaces nanocomposites VXG with polymetalated species

Anaíssi, Fauze Jacó

10 March 2000

Nesta tese investigamos o comportamento eletroquímico da matriz lamelar de xerogel de pentóxido de vanádio(V) hidratado (VXG), visando desenvolver interfaces moleculares e eletrodos modificados. A partir da suspensão do gel de V2O5.nH2O, geramos os filmes lamelares de VXG sobre a superfície do eletrodo de trabalho. Inicialmente, os filmes de VXG consistem de regiões heterogêneas, que podem ser diferenciadas espectroeletroquimicamente. Após tratamento eletroquímico, esses filmes atingem uma condição eletroquímica estacionária, sofrendo um colapso e formando uma estrutura tipo banda uniforme. Esses filmes de VXG condicionados, foram utilizados como interfaces de espécies moleculares eletroativas. Em paralelo, interagimos o VXG com a argila bentonita, e obtivemos um xerogel floculento verde em solução aquosa, denotado BV, cuja evidência mais forte dessa interação foi obtido pelo espectro de FTIR, em função do surgimento de um forte pico em 835 cm-1, atribuído ao estiramento V-O-Si. A interação com a zeólita13X, resultou num sólido amarelo devido à troca de íons Na+ pelo grupo VO3+, denotado ZV. A troca iônica foi evidenciada pela análise de ICP-AES, que determinou uma quantidade grande de íons Na+ na solução sobrenadante, aproximadamente 225 mg/L contra 28 e 25,4 mg/L das soluções originais de VXG e zeólita13X, respectivamente. Eletroquimicamente, os compósito BV e ZV, despontam como materiais modificadores de eletrodos muito atraentes, combinando a boa condutividade dos filmes de VXG com as propriedades de troca iônica e de intercalação das argilas e das zeólitas. / The electrochemical behavior of hydrated vanadium(V)-oxide xerogels (denoted VXG), has been investigated, aiming the development of molecular interfaces and modified electrodes. Layered vanadium(V)- oxide xerogel films have been generated, in a controlled way, by the direct deposition de precise amounts of the polyvanadic acid solution onto the electrode surface. Initially, the layered VGX films consist of heterogeneous regions, which can be differentiated spectroelectrochemically. However, after the electrochemical treatment, those films reach a stationary electrochemical condition, collapsing into a uniform band type structure. The conditioned layered VXG films have been utilized as interfaces of electroactive molecular species. In parallel, the VXG suspension has been combined with a montmorillonite clay, yielding a green flocculent xerogel in suspension, here denoted BV. Strong evidence of polyvanadate-bentonite interaction has been provided by the FTIR spectra, from the appearance of a strong peak in 835 cm-1, ascribed to the a new V-O.-Si stretching vibration. The VXG suspension has also been combined with zeolite 13X, resulting a yellow solid, envolving ionic exchange of Na+ ions by VO3+; this solid has been denoted ZV. Ionic exchange has been evidenced by ICP-AES analyses. A promissing use of the new materiaIs as molecular interfaces has been demonstated, exploiting the good conductivity and intercalation properties of VXG and BV, as well as, the ion exchange properties of ZV.

Collation

Electroactive species

Electrochemistry

Eletroquímica

Espécies eletroativas

Físico-química inorgânica

Inorganic physical chemistry

Intercalação

Interfaces moleculares

Molecular interfaces

Pentóxido de Vanádio

Vanadium pentoxide

Comprendre et optimiser les anodes microbiennes grâce aux technologies microsystèmes / Understanding and optimizing microbial anodes using microsystems technologies

Champigneux, Pierre

15 June 2018

De multiples micro-organismes ont la capacité de catalyser l’oxydation électrochimique de matières organiques en s’organisant en biofilm à la surface d’anodes. Ce processus est à la base de procédés électro-microbiens très innovants tels que les piles à combustible microbiennes ou les électrolyseurs microbiens. L’interface biofilm/électrode a été l’objet de nombreuses étudesdont les conclusions restent difficiles à démêler en partie du fait de la diversité des paramètres interfaciaux mis en jeu. L’objet de ce travail de thèse est d’exploiter les technologies microsystèmes pour focaliser l’impact de la topographie de surface des électrodes sur le développement du biofilm et sur ses performances électro-catalytiques. La formation de biofilmsélectroactifs de Geobacter sulfurreducens a été étudiée sur des électrodes d’or présentant des topographies bien contrôlées, sous la forme de rugosité, porosité, réseau de piliers, à des échellesallant du nanomètre à quelques centaines de micromètres. La présence de microrugosité a permis d’accroitre les densités de courant d’un facteur 8 par rapport à une surface lisse et son effet a étéquantifié à l’aide du paramètre Sa. Nous avons tenté de distinguer les effets des différentes échelles de rugosité sur le développement du biofilm et la vitesse des transferts électroniques.L’intérêt de la microporosité a été discuté. L’accroissement de surface active par la présence de micro-piliers s’est avéré très efficace et une approche théorique a donné des clés de compréhension et d’optimisation. Les connaissances acquises dans les conditions de culture pure ont finalement été confrontées avec la mise en oeuvre de biofilms multi-espèces issus d’un inoculum complexe provenant de sédiments marins. / Many microorganisms have the ability to catalyze the electrochemical oxidation of organic matterby self-organizing into biofilm on the surface of anodes. This process is the basis of highlyinnovative electro-microbial processes such as microbial fuel cells or microbial electrolysis cells.The biofilm/electrode interface has been the subject of numerous studies whose conclusionsremain difficult to disentangle partly because of the diversity of the interfacial parameters involved.The purpose of this thesis work is to exploit microsystem technologies to focus the impact ofelectrode surface topography on biofilm development and electro-catalytic performance. Theformation of electroactive biofilms of Geobacter sulfurreducens was studied on gold electrodespresenting well-controlled topographies, in the form of roughness, porosity, pillar networks, atscales ranging from nanometer to a few hundred micrometers. The presence of micro-roughnessincreased the current densities by a factor of 8 compared to a smooth surface and its effect wasquantified using the Sa parameter. We have tried to distinguish the effects of different roughnessscales on biofilm development and electron transfer rates. The suitability of micro-porosity wasdiscussed. The increase of active surface area by the presence of micro-pillars has proved veryeffective and a theoretical approach has given keys to understanding and optimization. Theknowledge acquired under pure culture conditions was finally confronted with the use of multispeciesbiofilms formed from a complex inoculum coming from marine sediments.

Bioanode

Rugosité

Biofilm électroactif

Adhésion bactérienne

Geobacter sulfurreducens

Systèmes bioélectrochimiques

Bioanode

Roughness

Electroactive biofilm

Bacterial adhesion

Geobacter sulfurreducens

Bioelectrochemical system

620

Biodiversités électroactives issues de sources hydrothermales profondes

Pillot, Guillaume

14 December 2018

Les sources hydrothermales profondes sont des édifices géologiques formés par l’infiltration d’eau de mer dans la croûte océanique, formant un fluide chaud (>400 °C), riche en métaux qui précipite pour former des cheminées dans lesquelles circulent un courant électrique. Les travaux de recherche présentés ici avaient pour objectif de révéler la présence de microorganismes capable de participer à la production de ce courant électrique ou d’utiliser cette électricité pour vivre au sein de ces cheminées électriquement conductrices. Nous nous sommes focalisés sur les microorganismes capables de survivre à haute température (entre 60 et 95°C). Différentes communautés microbienne en interaction et électroactives ont pu être cultivées permettant de poser des hypothèses crédibles quant à la colonisation primaire de ces environnements extrêmes. Ces hypothèses pourraient également s’appliquer aux théories d’origine de la vie en contexte hydrothermal. / Deep hydrothermal vents are geologic structures formed by the infiltration of seawater into the oceanic crust, forming a hot metal-rich fluid (> 400 ° C) that precipitates to form chimneys in which an electric current flows. The purpose of the research presented here was to reveal the presence of microorganisms capable of participating in the production of this electric current or of using this electricity to live within these electrically conductive chimneys. We focused on microorganisms able to survive at high temperatures (between 60 and 95 ° C). Different interacting and electroactive microbial communities have been cultivated, allowing the building of credible hypotheses about the primary colonization of these extreme environments. These hypotheses could also be applied to theories of origin of life in a hydrothermal context.

Source hydrothermale profonde

Ecologie microbienne

Biofilm électro-Actif

Pile à combustible microbienne

Electrosynthèse microbienne

Deep-Sea Hydrothermal Vent

Microbial Ecology

Electroactive Biofilm

Microbial Fuel Cell

Microbial Electrosynthesis

550

Amélioration des propriétés de conversion électromécanique dans les polymères électrostrictifs / Electromechanical property enhancement of electrostrictive polymers

Liu, Qin

29 March 2013

La thèse est consacrée aux matériaux électro-actifs, qui sont développés et conçus pour faire de la conversion entre énergie électrique et énergie mécanique. Avec les nouvelles technologies émergentes de transduction électromécanique, les polymères électro-actifs (EAP) ont gagné une attention considérable. Ils présentent de grandes déformations quand ils sont soumis à un champ électrique. Cependant, ces matériaux présentent de faibles permittivités et exigent pour fonctionner l’application de forts champs électriques. Les recherches entreprises dans la thèse traitent de différentes méthodes ayant pour but d'augmenter la permittivité des polymères et par conséquent d’améliorer les propriétés électromécaniques sous des champs électriques modérés. Les différentes approches consistent à la mise au point de nouveaux matériaux, par la méthode de mélange de polymères ou en utilisant un nouveau type de polymère, et par l'incorporation de nano-charges spéciales dans la matrice polymère. Un mélange de polyuréthane (PU) et PEMG obtenu à partir d'un procédé en solution conduit à des valeurs plus basses de module de Young, mais aussi à de plus faibles permittivités diélectriques. Il est cependant mis en évidence une amélioration des propriétés électromécaniques, par exemple, à le gain à des champs électriques modérés est d’un facteur 2, avec seulement 9% en poids de PEMG. Deux types de Pebax sont testés comme matrice polymère. Des valeurs très élevées de permittivités sont obtenus plus particulièrement pour le Pebax1657 mais liés pour ce matériau à des valeurs élevées de conductivité. En dépit de ces permittivités élevées, seule une légère amélioration de la conversion électromécanique est observée par rapport au polyurethane. Nous nous sommes également intéressés aux nanocomposites de polyuréthane basés sur desnanoparticules d'argent recouvertes de polymère polyvinylpyrrolidone (PVP). Un fin revêtement de polymère sur les nanoparticules d'argent conduit à une meilleure dispersion des charges dans les films de polyuréthane, et des valeurs plus élevées de permittivité. Différentes quantités d'Ag-PVP sont testées jusqu'au seuil de percolation proche de 45% en poids de charges. À partir des mesures par interférométrie laser et du nouveau dispositif de caractérisation croisée, les propriétés électromécaniques optimales sont obtenues pour 20% en poids de Ag-PVP, avecun gain de 2 à 6 par rapport au polyuréthane pur. Afin d'expliquer la différence entre les résultats expérimentaux et attendus, et par conséquent pour parvenir à une meilleure compréhension du comportement électromécanique de ces différents matériaux, certaines hypothèses ont été discutées et testées. Nous avons montré notamment une baisse des permittivités diélectriques sous champs électriques pour les Pebax et les nanocomposites, des problèmes d'absorption d'eau pour les Pebax et une diminution de cristallinité dans le cas des nanocomposites PU-Ag. / The thesis is devoted to electroactive materials, which are developed and designed to make conversion between the electricity and the mechanical form. With newer emerging electromechanical transduction technologies, electroactive polymers (EAP) have gained a considerable attention. The polymers are competitive in many applications such as actuators, sensors, robotic system and biological mimics since they are cheap, light, easy to process, and they present large electric field-induced strains. However, these materials suffer from the low permittivity and high voltage requirement to drive the actuations. The research undertaken for the thesis intends then to provide different methods in order to enhance the polymer permittivity and consequently the electromechanical activities at moderate electric fields. The different approaches consist on the development of new materials by polymer blend method or by using new kind of polymer, and on the incorporation of special nano-fillers in the polymer matrix. A blend of polyurethane (PU) and poly [ethylene-co-(methyl acrylate)-co-(glycidyl methacrylate) (PEMG) obtained from a simple solution method leads to lower values of Young modulus but also lower dielectric permittivities. The PU-PEMG blend presents however an improvement of the electromechanical capabilities, for example it is obtained a two fold increase of the strain at moderate fields with only 9%wt of PEMG.Two types of Polyetherblockamide (Pebax) are tested as polymer matrix. Very high values of permittivities are obtained particulary for Pebax1657 but accompanied for this material by high values of conductivity. Despite these high permittivities (more than 200000 for Pebax 1657 and 500 for Pebax 2533 at 0.1 Hz), only a moderate improvement of the electromechanical capability is observed compared to PU. We are also intererested on polyurethane nanocomposites based on silver nanoparticles coverered by PolyVinylPyrrolidone (PVP) polymer. A little polymer coating of the nanosilver leads to a better dispersion into the polyurethane films and higher values of permittivity. Different amounts of Ag-PVP are tested up to the percolation threshold close to 45%wt of fillers. Based on laser interferometer measurements and new cross characterization device, the optimal electromechanical properties are obtained for 20 %wt of Ag-PVP and a gain of 2 to 6 is obtained compared to pure polyurethane. In order to explain the difference between experimental and expected results and consequently to achieve a better understanding of the electromechanical behaviour of these different materials, some hypotheses were discussed and tested. We have shown particularly a drop of dielectric permittivities under electric fields for Pebax and nanocomposites, some problems of water absorption for Pebax and a decrease of crystallinity for the PU-Ag nanocomposites.

Nanocomposite à matrice polymère

Polymère électroactif

Polyuréthane

Pemg

Permittivité

Pebax

Matériau diélectrique

Polymer matrix nanocomposite

Electroactive polymer

Polyurethane

Pemg

Permittivity

Dielectric Materials

620.192 118 072

Couplage multiphysique à l’aide d’électret application à la récupération d’énergie / Multiphysics coupling with electret application to the Harvesting energy

Belhora, Fouad

07 December 2013

Les matériaux actifs, tels que les matériaux piézoélectriques et électrostrictifs, sont couramment utilisés dans la conception de dispositifs exploitant leurs propriétés respectives. La propriété principale de ces matériaux réside dans le fort couplage entre les comportements électrique et mécanique (piézoélectricité). Dans la majorité des cas, ces matériaux sont utilisés séparément. L’utilisation combinée de ces matériaux permet la réalisation de dispositifs innovants basés sur l’effet électrostrictifs: l’apparition d’une polarisation électrique induite par une contrainte mécanique et réciproquement l’apparition d’une déformation mécanique sous l’action d’un champ électrique. Les applications « support » concernent les capteurs et les actionneurs. L’étude de ce couplage passe par la caractérisation de ces matériaux, puis par la mise en place de modèles décrivant finement leurs comportements et enfin par le développement d’outils pour la conception. L’objectif de la thèse est de remplacer le matériau céramique, rigide et à faible déformation, par un film polymère nanocomposite électroactifs, présentant des grandes déformations et forces d'actionnement sous champ électrique modéré grâce à l'incorporation dans la matrice polymère de micro et nano-objets (charge) conducteurs ou semi-conducteurs. De plus, pour des applications plus spécifiques de la récupération d’énergie, la charge du film polymère par des micro et nano-objets conducteurs sera également étudiée. Idéalement, il serait très intéressant de réaliser un matériau multifonctionnel, sensible à la fois à une stimulation mécanique (propriétés de détection et/ou de récupération d’énergie par couplage électromécanique). / In the last decades, direct energy conversion devices for medium and low grades waste heat have received significant attention due to the necessity to develop more energy efficient engineering systems. A great deal of research has in recent years been carried out on harvesting energy using piezoelectric, electrostatic, electromagnetic , and thermoelectric ,transduction, with the aim of harvesting enough energy to enable data transmission. For this purpose, piezoelectric elements have been extensively used in the past; however they present high rigidity and limited mechanical strain abilities as well as delicate manufacturing process for complex shapes, making them unsuitable in many applications. Thus, recent trends in both industrial and research fields have focused on electrostrictive polymers for electromechanical energy conversion. This interest is explained by many advantages such as high productivity, flexibility, and processability. Hence, electrostrictive polymer films are much more suitable for energy harvesting devices requiring high flexibilities, such as systems in smart textiles and mobile or autonomous devices. Electrostrictive polymers can also be obtained in many different shapes and over large surfaces. . In the last years, electrostrictive polymers have been investigated as electroactive materials for energy harvesting. However for scavenging energy a static field is necessary, since this material is isotope, there is no permanent polarization compare to piezoelectric material. A solution for avoid this problem; concern the hybridization of electrostrictive polymer with electret. Finally, the implementation of electrostrictive materials is much simpler for small-scale systems (MEMS). Hence, several studies have analyzed the energy conversion performance of electrostrictive polymers, both in terms of actuation and energy harvesting.

Energétique

Récupération d'énergie

Electret

Matériau piézoélectrique

Effet électrostrictif

Polymère électro-Actifs

Conversion électromécanique

Energetics

Energy harvesting

Electret

Piezoelectric Materials

Electrostrictive polymer

Electroactive polymer

Electromechanical Conversion

536.230 72

Nouvelles structures à polymères électroactifs / New electroactive polymers structures

Cornogolub, Alexandru

08 April 2016

Ces travaux de thèse se veulent exploratoires et visent à proposer d’une part une nouvelle approche hybride piézoélectrique-polymère pour le développement de récupérateur d’énergie et d’autre part à développer des méthodes d’actionnement destinée au contrôle de forme structurelle. L’utilisation de polymères diélectriques dans les dispositifs de récupération d’énergie permet de concilier une densité énergétique élevée avec une faible rigidité et une simplicité de mise en œuvre. L’approche hybride proposée dans le cadre de ces travaux permet de s’affranchir de la source de polarisation externe en la substituant par un dispositif piézoélectrique apte à générer, sous l’action d’une contrainte mécanique, le champ électrique nécessaire au fonctionnement du dispositif. L’optimisation du transfert d’énergie entre deux systèmes supposé quelconque a d’abord été généralisée. Les travaux ont ensuite été orientés vers l’investigation de la faisabilité de l’approche hybride piezo-polymère. Les performances des dispositifs hybrides ont été évaluées expérimentalement et comparées à celles obtenues avec des récupérateurs piézoélectriques simples et avec des récupérateurs polymères à polarisation externe. Il est montré que l’utilisation d’un dispositif hybride permet de concilier les qualités des deux approches simples, à savoir la faculté d’initier le processus de conversion d’énergie grâce au champ électrique généré par l’élément piézoélectrique et d’exploiter la haute densité d’énergie des polymères. La deuxième partie de ces travaux porte sur l’utilisation de matériaux électroactifs comme dispositifs d’actionnement destinés au contrôle de forme de structures minces. L’application finale visée ici est le développement de matériau de type peau active. Différents types de polymères ont d’abord été testés et leur performances ont été comparées avec des modèles théoriques spécifiquement développés. Des structures originales ont été proposées pour solutionner certains problèmes liés à l’actionnement par polymères diélectriques. Des prototypes simples ont permis de valider le principe du contrôle de forme des structures à l’aide de polymères diélectriques. / Dielectric polymers have seen their importance grow in the field of electroactive materials because of their undeniable advantages, particularly for potential applications such as energy harvesting, actuation or sensors. The work done in this thesis is exploratory and aims primarily to provide on one hand a new piezoelectric-polymer hybrid approach for the development of energy harvesting systems and secondly to develop operating methods shape control of structures using electroactive polymers. The use of dielectric polymers in energy harvesting devices reconciles a high energy density with low rigidity and simplicity of integration. The main problem which is characteristic of such devices is that they necessarily require the use of an external bias high voltage supply (> 1kV) to achieve significant energy densities. The hybrid approach proposed in the context of this work eliminates this source of external energy by using a piezoelectric device capable of generating, under the action of a mechanical stress, the electric field required to operate the device. The problem of optimization of energy transfer between any two systems was also studied. The work was then directed towards the investigation of the feasibility of the piezo-polymer hybrid approach. Various configurations have been proposed and evaluated in order to deduce their optimal parameters. The performance of hybrid devices was experimentally evaluated and compared with that obtained with simple piezoelectric or electrostatic (using polymers) systems. The second part of this work focuses on the use of electroactive materials as actuators for shape control of thin structures. The final application aimed here is the development of an active skin type material allowing reconfiguration of orbiting satellite antennas. Different types of polymers were first tested and their performance has been compared with the theoretical models developed specifically in this context. Original structures have been proposed to solve some problems related to the actuation using dielectric polymers. Simple prototypes have validated the principle of the structural shape control. If their use brings undeniable advantages over conventional operating techniques, the fact remains that certain specific characteristics of electroactive polymers limit their performance. For example, the square law characteristic of the electroactive polymer control requires the use of particular geometries in order to obtain a symmetrical two-way displacement. This fact complicates the control of such actuators but allows in the end to add new features. Thus the use of a sectored network of polymer actuator is required to obtain a symmetrical movement on a single type of structure blocked blocked-beam, but allows to consider different deformation profiles. Other similar problems have been addressed using different original structures.

Electrotechnique

Matériel électroactif

Polymère diélectrique

Matériau piézoélectrique

Contrôle de forme

Récupération d'énergie

Electrotechnics

Electroactive material

Piezoelectric Materials

Shape control

Energy Harvesting

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Development of electrostrictive P(VDF-TrFE-CTFE) terpolymer for inkjet printed electromechanical devices / Développement d'un terpolymère électrostrictif P(VDF-TrFE-CTFE) pour des dispositifs électromécaniques imprimés par jet d'encre

Liu, Qing

29 November 2016

Les polymères ferroélectriques et plus récemment les matériaux électrostrictifs ont attiré l’attention de la communauté scientifique en raison de leur capacité de conversion d’une excitation électrique en une réponse mécanique et vice versa. La synergie entre les propriétés électro actives de ces polymères et leurs propriétés physico-chimiques intrinsèques (souplesse, légèreté, grande résistance mécanique, facilité de mise en œuvre etc.) en font des candidats de choix pour des applications de types capteurs et actionneurs souples. Cette thèse vise à déterminer de façon systématique le comportement électromécanique des terpolymères P (fluorure de vinylidène-trifluoréthylène-chlorotrifluoroéthylène) [P (VDF-TrFE-CTFE)] par des techniques de cristallisation et de technologies additives et entend étendre ces terpolymères à l'application des dispositifs de type capteur de force électromécanique. L'influence du traitement thermique sur la réponse électromécanique et la microstructure des terpolymères a d'abord été étudiée. Il a été mis en évidence que la déformation électrostrictive transversale S31 pour chaque terpolymère traité thermiquement suit une loi quadratique avec le champ électrique. Par ailleurs il a été démontré que la déflexion d’un actionneur unimorphe est maximisée pour une fraction de phase cristalline de 39,3%. La dynamique moléculaire des terpolymères cristallisés a également été étudiée par spectroscopie diélectrique à large bande. Une dynamique segmentaire contrainte a été observée dans le terpolymère contenant la fraction cristalline la plus élevée pour laquelle une distribution étroite du temps de relaxation a été mise en évidence. En outre, il a été démontré que l’ajout d’agent plastifiant permet d’augmenter de manière significative la réponse électromécanique des terpolymères fluorés, ouvrant la voie vers de nouveaux matériaux électrostrictifs hautes performances fonctionnant sous faible champ électrique. De plus, la réponse diélectrique et électromécanique accrue du terpolymère dopé a été étudiée par microscope à force atomique et spectroscopie diélectrique dynamique. Ces analyses ont permis de lier l’augmentation de la réponse électromécanique de ces mélanges à un effet de polarisation interfaciale intensifié lors de l’augmentation de mobilité moléculaire de la phase amorphe rigide de ces terpolymères fluorés. Enfin, des dispositifs électromécaniques basés sur le polymère ferroélectrique P (VDF-TrFE) et le terpolymère électrostrictif P (VDF-TrFE-CTFE) ont été élaborés. Un procédé de fabrication additive utilisant la technologie d'impression jet d'encre a permis de concevoir et valider la faisabilité de réalisation de capteurs de force dynamique. Il a alors été démontré que les propriétés pseudo-piézoélectriques du terpolymère électrostrictif sont équivalentes à celles du copolymère ferroélectrique pour un faible champ électrique de biais de 7,5 V /μ / Electromechanical coupling effect has been paid the increasing attention due to ability to realize conversion between electric excitation and mechanical response and vice versa. Thanks to their flexibility, light weight, relatively low mechanical strength, ease of processability into large-area films, and ability to be molded into desirable geometric dimensions, polymers materials which possess an electromechanical coupling effect have been emerging recently. This thesis aims to systematically determine the electromechanical behavior of the P(vinylidene fluoride-trifluoroethylene-chlorotrifluoroethylene) [P(VDF-TrFE-CTFE)] terpolymers via crystallization and additive technology approaches and intend to extend such terpolymers to the electromechanical force sensor devices application. The influence of the thermal processing on the electromechanical response and microstructure of the terpolymers were firstly investigated. Cantilever unimorph bending measurement found the tip displacement δ and transverse strain S_31 for each thermally treated terpolymer followed a quadratic correlation with the electric field. δ was maximized at a 39.3% crystal content, instead of S_31 peaking at lowest crystal content, showing an exponential decay against the crystal fraction increasing. The dynamics of crystallized terpolymers were additionally studied via broadband dielectric spectroscopy. Constrained segmental dynamics was observed in the terpolymer containing the highest crystal fraction for which a narrow relaxation time distribution was found. Moreover, the enhanced dielectric and electromechanical response of DEHP doped terpolymer were interpreted via morphology microstructure and molecular mobility analysis. Interfacial polarization shifted to the high frequency by one decade because of dopant DEHP. Finally, electromechanical devices based on ferroelectric P(VDF-TrFE) and electrostrictive P(VDF-TrFE-CTFE) towards the dynamic force sensor implementation were designed and fabricated via inkjet printing technology. The bias electric field for terpolymer sensor was much lower than the poling electric field for a copolymer sensor. And the piezoelectric properties equivalent to the corresponding copolymer sensor can be obtained for a bias as low as 7.5 V/μ

Dispositifs électromécaniques

Impression jet d'encre

Fabrication additive

Polymères électroactifs

Capteur

Actionneurs

Dynamique moléculaire

Plastifiants

Electromechanical devices

Inkjet printing

Additive manufacturing

Electroactive polymers

Actuators

Molecular dynamics

Plasticisers

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