Fluoropolymers functionalized by phosphorous and silicon groups. Syntheses, characterization and applications. / Fluoropolymères fonctionnalisés par des groupes phosphore et silicium. Synthèses, caractérisation et applications.

Wehbi, Mohammad

30 November 2018

Les polymères fluorés sont des macromolécules intéressantes qui, en raison de leurs propriétés uniques, sont souvent utilisées dans des applications spéciales dans les industries du bâtiment, de l'aérospatiale, du génie chimique, du traitement des textiles, optiques et de la microélectronique. Cette thèse se concentre sur le développement de polymères fluorés fonctionnels à base de phosphore et de silane par la co/terpolymérisation radicalaire conventionnelle de monomères fonctionnels avec le fluorure de vinylidène (VDF). Ces monomères fonctionnels ont été préparés à partir de la modification de l'acide 2- (trifluorométhyl) acrylique (MAF) pour préparer des MAF-ester avec le groupement fonctionnel souhaité. Tout d'abord, une étude fondamentale concernant la cinétique de polymérisation du VDF avec MAF-TBE a montré que ces paires de monomères ont une tendance à se propager de manière croisée, ce qui donne des copolymères alternés. On a ensuite préparé du MAF avec une fonction phosphonate (MAF-DMP) et sa copolymérisation avec du VDF a permis d'obtenir du PVDF à fonctionnalité phosphonate qui, après l'hydrolyse consécutive du groupe phosphonate en acide phosphonique, avait des propriétés anticorrosion sur l'acier. De façon similaire, un monomère de MAF porteur une fonction carbonate cyclique (MAF-cyCB) a également été copolymérisé avec du VDF. Les groupes carbonate cycliques dans le copolymère de PVDF obtenu ont ensuite été ouverts par 1'aminopropyltriéthoxysilane pour introduire un groupe silane, qui, par son hydrolyse, a permis au copolymère d'adhérer fortement sur les substrats. Enfin, un terpolymère à base de PVDF fonctionnel porteur à la fois un groupe phosphonate et un groupe triéthoxysilane a été préparé. Le groupe silane a ensuite été hydrolyse et réticulé pour obtenir un réseau 3D de polymères. Enfin, l'hydrolyse du groupe phosphonate en acide phosphonique a conduit à une matière pouvant être utilisée dans l'extraction des ions Eu (III) de l'eau. / Fluorinated polymers are intresting macromolecules which due to their unique properties are often used in special applications in building industries, aerospace, chemical engineering, optics, textile treatment and microelectronics. This thesis focusses on the development of phosphorous and silane functional fluorinated polymers through the conventional radical co/terpolymerization of functional monomers with vinylidene difluoride (VDF). These functional monomers were prepared from the modification of 2-(Trifluoromethyl)acrylic acid (MAF) to prepare MAF-esters with the desired functional group. First a fundamental study regarding the kinetics of polymerization of VDF with MAF-TBE revealed that these monomer pair tends to cross propagate resulting in an alternating copolymer. Phosphonate functional MAF (MAF-DMP) was then prepared and its copolymerization with VDF led to phophonate functional PVDF, that after the consequent hydrolysis of the phosphonate group into phosphonic acid showed anticorrosion properties to steel. Following the same concept, a cyclic carbonate functional MAF monomer (MAF-cyCB) was also copolymerized with VDF. The cyclic carbonate groups in the obtained PVDF copolymer was then opened by aminopropyltriethoxysilane to introduce a silane group, that by its hydrolysis allowed the copolymer to adhere strongly onto substrates. Finally, a terpolymer based on PVDF functional with both a phosphonate and a triethoxysilane group is prepared. The silane group was then hydrolyzed and crosslinked to obtain a 3D network of polymers. Finally, the hydrolysis of the phosphonate group into phosphonic acid led to material that can be employed in Eu(III) ion extraction from water.

Matériaux hybrides

Matériaux hybrides

Phosphonate

Silane

Pvdf

Hybrid material

Hybrid material

Sol-Gel

Silane

Pvdf

Synthesis and characterization of sol-gel derived PI/silica hybrid material for low dielectric constant application

Hu, Yu-cheng

24 July 2004

Sol-gel process was utilized to produce organic/inorganic composite in this research, and the effect of mixing time¡]of polymer¡¦s and silica¡¦s precursor¡^ and coupling agent were investigated. To get low к materials was also the important objective. TMA, TGA, SEM, FT-IR, and RF impedance were used to investigate thermal properties, chemical bonding, morphology, and dielectric constant, respectively. The experiments showed that mixing time influence little to thermal stability but a lot to morphology and к. When mixing time was nearer to reaction time, the particle of silica was larger and the surface was flatter. The materials with coupling agent didn¡¦t show the same tendency as one without coupling agent. Regardless of coupling agent, it got larger к when mixing time was nearer to reaction time. Comparing with pure polymer, the modified materials got lower к. The lowest к got in this research was 2.36 which was lower than other materials.

GPTMS

PI

TEOS

6FDA

ODA

IPTS

hybrid material

dielectric constant

Study of hybrid materials composed of PMMA and silica prepared via the sol-gel technique

Cheng, Shun-Yu

30 July 2001

Abstract This study focused on the structure of the particles developed in the PMMA matrix as a function of (a) coupling agent (£^-MPS) and (b) TEOS content. We investigated the difference of using TEOS monomer directly added to silica particles. The polymer precursors are catalyzed using acidic catalysts and undergo the sol-gel reaction to form a hybrid sol-gel material. This composite shows that highly optical transparency and microphase separation at the molecular level. The characteristics and properties of the polymer precursors and their hybrid materials were characterized by Fourier-transform infrared spectroscopy (FTIR), differential scanning calorimetry (DSC), and thermogravimogravimetic analysis (TGA). As for the influence of chemistry structure on morphology and thermal properties, experimental evidence form observations by scanning electron microscopy (SEM), mulitpoints analysis, and transmission electron microscopy (TEM). TEM was used to study the phase separation as well as the fractal structure of these particles present in the system. According to some result, it was found the compatibility between PMMA and silica mainly comes form incorporating the polymer with silica chemical bonding. This chemical bonding not only restrains silyl ester groups form hydrolyzing but also reduces silanol aggregation. Moreover, the thermal properties of the organic¡Vinorganic hybrid are improved as silica content increases.

morphology

TEM

TEOS

sol-gel

hybrid material

PMMA

Cellulose/gold nanocrystal hybrids via an ionic liquid/aqueous precipitation route

Li, Zhonghao, Taubert, Andreas

January 2009

Injection of a mixture of HAuCl4 and cellulose dissolved in the ionic liquid (IL) 1-butyl-3-methylimidazolium chloride [Bmim]Cl into aqueous NaBH4 leads to colloidal gold nanoparticle/cellulose hybrid precipitates. This process is a model example for a very simple and generic approach towards (noble) metal/cellulose hybrids, which could find applications in sensing, sterile filtration, or as biomaterials.

Cellulose

Gold nanoparticles

Ionic liquid

Precipitation

Hybrid material

Chemistry and allied sciences

Development and Characterization of Ethanol-Compatibilized PPO-Based EPMM Membranes

Wang, Qiang

22 August 2011

Emulsion polymerized mixed matrix (EPMM) membranes is a new category of membranes, which incorporate silica-based inorganic nanoparticles dispersed in continuous phase of an organic polymer. The uniqueness of the EPMM membranes comes from the fact that they may combine otherwise incompatible inorganic and organic phases. This is achieved by the synthesis of the inorganic nanoparticles from a silica precursor in a stable emulsion, in which an aqueous phase is dispersed in a continuous phase of the polymer solution. More specifically, the silica precursor soluble in the polymer solution polymerizes in contact with the aqueous phase, and consequently the latter acts as finely dispersed micro reactors. The objective of this work was to optimize the previously developed protocol for the synthesis of poly (2,6-dimethyl-1,4pheneylene oxide) (PPO) based EPMM membranes, and to characterize their physical and gas transport properties. In particular, the effects of inorganic loading and the membrane post-treatment protocol on the permeability and selectivity of the membranes were of interest. However, the results showed that the obtained permeation and separation were virtually not affected by the theoretical Si loading and the post-treatment protocol. Moreover, in comparison to the base PPO membranes, the observed O2 permeability and the O2/N2 permselectivity have generally decreased. The differential scanning calorimetry (DSC) analysis of the synthesized membranes showed an important scatter of the glass transition temperatures (Tg) of the EPMM membranes with the values generally lower than the Tg of the base PPO. Moreover, the inductively coupled plasma mass spectrometry (ICP-MS) showed the silica content in selected EPMM membranes to be far below the expected theoretical level. This, in combination with the 29Si nuclear magnetic resonance (29Si NMR) results, showed that most of the already low silica content comes from the unreacted silica source (tetraethylorthosilicate) and have led to the second phase of the project in which a modified synthesis protocol has been developed. The major differences of the modified protocol compared to the original one include the replacement of a surfactant, 1-octanol, by ethanol and using greater concentrations of the reactants. To study the effect of different parameters involved in the synthesis protocol, a Gravimetric Powder experiment, in which the inorganic polymerization is carried out in an emulsion with a pure solvent rather than a polymer solution, has been designed. The Gravimetric Powder experiments have confirmed polymerization of tetraethylorthosilicate (TEOS) in the emulsion system. Using the conditions, which resulted in the maximum production of the polymerized TEOS in the Gravimetric Powder experiments, one set of new EPMM membranes has been synthesized and characterized. The new EPMM membranes have the Tg of 228.2oC, which is distinctly greater compared to the base PPO, and contain one order of magnitude more of silica compared to the old EPMM membranes. More importantly, the 29Si NMR analysis has proven that the silica content in the new EPMM membranes originates from the reacted rather than unreacted TEOS. Interestingly, the observed conversion of TEOS in the new EPMM membranes, exceeding 20%, is greater than the largest conversion in the Gravimetric Powder experiments. The oxygen permeability in the new EPMM membrane of 33.8 Barrer is more than twice that of the base PPO membrane. Moreover, this increase in O2 permeability is associated with a modest increase in the O2/N2 permselectivity (4.75 versus 4.67).

EPMM membrane

Hybrid Material

Gas separation membrane

PPO-Based

Ethanol-Compatibilized

Development and Characterization of Ethanol-Compatibilized PPO-Based EPMM Membranes

Wang, Qiang

22 August 2011

Emulsion polymerized mixed matrix (EPMM) membranes is a new category of membranes, which incorporate silica-based inorganic nanoparticles dispersed in continuous phase of an organic polymer. The uniqueness of the EPMM membranes comes from the fact that they may combine otherwise incompatible inorganic and organic phases. This is achieved by the synthesis of the inorganic nanoparticles from a silica precursor in a stable emulsion, in which an aqueous phase is dispersed in a continuous phase of the polymer solution. More specifically, the silica precursor soluble in the polymer solution polymerizes in contact with the aqueous phase, and consequently the latter acts as finely dispersed micro reactors. The objective of this work was to optimize the previously developed protocol for the synthesis of poly (2,6-dimethyl-1,4pheneylene oxide) (PPO) based EPMM membranes, and to characterize their physical and gas transport properties. In particular, the effects of inorganic loading and the membrane post-treatment protocol on the permeability and selectivity of the membranes were of interest. However, the results showed that the obtained permeation and separation were virtually not affected by the theoretical Si loading and the post-treatment protocol. Moreover, in comparison to the base PPO membranes, the observed O2 permeability and the O2/N2 permselectivity have generally decreased. The differential scanning calorimetry (DSC) analysis of the synthesized membranes showed an important scatter of the glass transition temperatures (Tg) of the EPMM membranes with the values generally lower than the Tg of the base PPO. Moreover, the inductively coupled plasma mass spectrometry (ICP-MS) showed the silica content in selected EPMM membranes to be far below the expected theoretical level. This, in combination with the 29Si nuclear magnetic resonance (29Si NMR) results, showed that most of the already low silica content comes from the unreacted silica source (tetraethylorthosilicate) and have led to the second phase of the project in which a modified synthesis protocol has been developed. The major differences of the modified protocol compared to the original one include the replacement of a surfactant, 1-octanol, by ethanol and using greater concentrations of the reactants. To study the effect of different parameters involved in the synthesis protocol, a Gravimetric Powder experiment, in which the inorganic polymerization is carried out in an emulsion with a pure solvent rather than a polymer solution, has been designed. The Gravimetric Powder experiments have confirmed polymerization of tetraethylorthosilicate (TEOS) in the emulsion system. Using the conditions, which resulted in the maximum production of the polymerized TEOS in the Gravimetric Powder experiments, one set of new EPMM membranes has been synthesized and characterized. The new EPMM membranes have the Tg of 228.2oC, which is distinctly greater compared to the base PPO, and contain one order of magnitude more of silica compared to the old EPMM membranes. More importantly, the 29Si NMR analysis has proven that the silica content in the new EPMM membranes originates from the reacted rather than unreacted TEOS. Interestingly, the observed conversion of TEOS in the new EPMM membranes, exceeding 20%, is greater than the largest conversion in the Gravimetric Powder experiments. The oxygen permeability in the new EPMM membrane of 33.8 Barrer is more than twice that of the base PPO membrane. Moreover, this increase in O2 permeability is associated with a modest increase in the O2/N2 permselectivity (4.75 versus 4.67).

EPMM membrane

Hybrid Material

Gas separation membrane

PPO-Based

Ethanol-Compatibilized

The characterization of SiO2-PEG hybrid materials prepared with sol-gel method and their applications to alcohol purification

Wu, Cheng-Hsien

03 August 2012

Abstract This thesis conducts a comprehensive investigation of the of the physical chemistry related to the TEOS-based porous materials prepared by so-gel approach and develops the fast qualification technology for the hydrolysis and condensation reaction of sol-gel process. The porous materials were prepared by introducing a polymer polyethylene glycol (PEG) into sol-gel after different aging times and with different drying and annealing processes. The effects of pH and addition of PEG on sol-gel derived SiO2 powders for purification of ethanol are studied. The methods and results of this work provide valuable reference for the development of other functional materials such as low k dielectric materials. In the first part, the long-term behavior of the hydrolysis and condensation reaction of the tetraethoxysilane (TEOS) pre-solution at different pH values with and without addition of polyethyleneglycol (PEG) for various aging times was characterized by liquid 1H, 13C, and 29Si NMR spectroscopy.The experimental results demonstrate that alcohol was generated in the TEOS pre-solutions with and without addition of PEG at pH 3 and pH 9 after aging, implying the occurrence of hydrolysis and condensation. The rate of hydrolysis and condensation for the TEOS pre-solution at pH 3 was found to follow the trend of the pre-solution with PEG 2000 > pre-solution with PEG 200 > pre-solution without PEG. However, after adding PEG, the oxygen atom of the deprotonated silanol group (siloxy) of the hydrolyzed TEOS pre-solution at pH3 acted as a reaction center. The result indicates that the oxygen atom is more susceptible to electrophilic attack, resulting in an increased reaction rate. Consequently, the rate of hydrolysis and condensation for of the TEOS pre-solution at pH 9 follows a different order: pre-solution with PEG 200 > pre-solution without PEG > presolution with PEG 2000. The slowest reaction rate of the TEOS pre-solution when adding PEG 2000 is related to the tangled chains of PEG 2000 which sterically reduces the hydrolysis and condensation reaction. This work shows that the correlation between the pH and aging time on hydrolysis and condensation reaction of the TEOS pre-solution can be effectively monitored by liquid 1H NMR spectroscopy, supported by 13C and 29Si liquid NMR spectra. The data obtained should assist optimizing the pH, polymer type/size/concentration and the aging time in the preparation of polymer modified TEOS sols In the second part, SiO2 powders were prepared by the sol-gel in combination with oven-drying method before and after annealing.The experimental result demonstrates the rate of hydrolysis and condensation occurs at a fast rate in TEOS with and without adding PEG at pH3 than in any other pH levels. Because free space can lead to the vaporization of H2O, the ionization of ammonia decreases (i.e., reduction the amount of hydroxide ion), which arises from the rate of hydrolysis and condensation decreases when TEOS at pH9. After attaching PEG, the oxygen atom of the deprotonated silanol group (siloxy) for of the hydrolyzed TEOS pre-solution at pH 3 acted as a reaction center. The result indicates the oxygen atom is more susceptible to electrophilic attack, resulting in an increased reaction rate. Thus, a maximum in the powder yield is reached for TEOS pre-solution with and without adding PEG at pH 3. The SiO2 powder with adding PEG of higher molecular weight presents higher adsorption capacities, pertaining to a greater amount of hydrophilic hydroxyl groups of PEG with higher molecular weight. After annealing, the surface area of SiO2 powder prepared from the TEOS pre-solutions increases as compared with powder without adding PEG and enhances the adsorption of water. A potential absorbent SiO2 powders for producing purified ethanol suitable for fuel and industrial use, can be fabricated by using sol-gel route by careful selection of pH and PEG molecular weight. In addition, during the preparation and characterization of these materials, some interesting phenomena were observed, which are academically valuable. For instance, some samples show very narrow 1H MAS spectra and yet has high 1H-29Si CPMAS sensitivety. This phenomenon suggests us that CPMAS sensitivety may be improved by a new route, i.e., by properly preparing the sample so that CP efficiency is enhanced.

NMR

Condensation

TEOS

PEG

Porous Material

Organic-Inorganic Hybrid Material

Sol-Gel

Hydrolysis

Ethanol Purification

Development and Characterization of Ethanol-Compatibilized PPO-Based EPMM Membranes

Wang, Qiang

22 August 2011

Emulsion polymerized mixed matrix (EPMM) membranes is a new category of membranes, which incorporate silica-based inorganic nanoparticles dispersed in continuous phase of an organic polymer. The uniqueness of the EPMM membranes comes from the fact that they may combine otherwise incompatible inorganic and organic phases. This is achieved by the synthesis of the inorganic nanoparticles from a silica precursor in a stable emulsion, in which an aqueous phase is dispersed in a continuous phase of the polymer solution. More specifically, the silica precursor soluble in the polymer solution polymerizes in contact with the aqueous phase, and consequently the latter acts as finely dispersed micro reactors. The objective of this work was to optimize the previously developed protocol for the synthesis of poly (2,6-dimethyl-1,4pheneylene oxide) (PPO) based EPMM membranes, and to characterize their physical and gas transport properties. In particular, the effects of inorganic loading and the membrane post-treatment protocol on the permeability and selectivity of the membranes were of interest. However, the results showed that the obtained permeation and separation were virtually not affected by the theoretical Si loading and the post-treatment protocol. Moreover, in comparison to the base PPO membranes, the observed O2 permeability and the O2/N2 permselectivity have generally decreased. The differential scanning calorimetry (DSC) analysis of the synthesized membranes showed an important scatter of the glass transition temperatures (Tg) of the EPMM membranes with the values generally lower than the Tg of the base PPO. Moreover, the inductively coupled plasma mass spectrometry (ICP-MS) showed the silica content in selected EPMM membranes to be far below the expected theoretical level. This, in combination with the 29Si nuclear magnetic resonance (29Si NMR) results, showed that most of the already low silica content comes from the unreacted silica source (tetraethylorthosilicate) and have led to the second phase of the project in which a modified synthesis protocol has been developed. The major differences of the modified protocol compared to the original one include the replacement of a surfactant, 1-octanol, by ethanol and using greater concentrations of the reactants. To study the effect of different parameters involved in the synthesis protocol, a Gravimetric Powder experiment, in which the inorganic polymerization is carried out in an emulsion with a pure solvent rather than a polymer solution, has been designed. The Gravimetric Powder experiments have confirmed polymerization of tetraethylorthosilicate (TEOS) in the emulsion system. Using the conditions, which resulted in the maximum production of the polymerized TEOS in the Gravimetric Powder experiments, one set of new EPMM membranes has been synthesized and characterized. The new EPMM membranes have the Tg of 228.2oC, which is distinctly greater compared to the base PPO, and contain one order of magnitude more of silica compared to the old EPMM membranes. More importantly, the 29Si NMR analysis has proven that the silica content in the new EPMM membranes originates from the reacted rather than unreacted TEOS. Interestingly, the observed conversion of TEOS in the new EPMM membranes, exceeding 20%, is greater than the largest conversion in the Gravimetric Powder experiments. The oxygen permeability in the new EPMM membrane of 33.8 Barrer is more than twice that of the base PPO membrane. Moreover, this increase in O2 permeability is associated with a modest increase in the O2/N2 permselectivity (4.75 versus 4.67).

EPMM membrane

Hybrid Material

Gas separation membrane

PPO-Based

Ethanol-Compatibilized

Functionalization and metallization of diamondoids / Fonctionnalisation et métallisation des diamantoïdes

Gunawan, Maria Agatha E.

21 May 2015

Ces travaux de thèse développent des méthodes pour la synthèse de nouveaux organohybrides carbone-métal basés sur les diamantoïdes et le palladium.Les pressions de vapeur de divers diamantoïdes ont été mesurées grâce à un protocole original de mesures de l'état d'équilibre thermodynamique solide-vapeur. Leur relative volatilité a permis de réaliser des dépôts de diamontoïdes en phase vapeur, à diverses pressions (ambiante, vide primaire, et vide poussé) sur des substrats comme le silicium ou le mica. Les observations au MEB ont montré que, selon le type de groupes fonctionnels présents sur le diamantoïde, différentes formes cristallines peuvent être produites (tiges, aiguilles, triangles, formes octaédriques tronquées).L’OMCVD de palladium sur les diamantanes fonctionnalisés montre que le palladium se dépose préférentiellement sur le substrat du silicium plutôt que sur les cristaux de diamantoïdes portant des groupes hydroxy ou fluor. Nous avons alors envisagé la synthèse de nouveaux diamontoïdes portant des groupes phosphino, qui pourraient former une liaison covalente entre le diamontoïde modifié et le palladium.Un ensemble complet de diamondoïdes fonctionnalisés par des phosphines a été synthétisé. Certaines nouvelles phosphines primaires ont révélées une stabilité à l’air inattendue.Il a été montré que l’utilisation de phosphine P(III) comme sites d'ancrage a permis la formation du matériau hybride Pd@PH2-Diam-OH. Différents caractérisations (XPS, MEB, MET, et EDX) ont montré que le matériau Pd@PH2-Diam-OH formé est isolant, et présente des interactions Pd–P. / The thesis deals with development of synthetic methods for preparation of novel carbon-metal organohybrid based on diamondoid and palladium. The vapor pressure of various diamondoids was measured from a new measurement protocol at solid-vapor thermodynamic equilibrium state. Their volatile tendency opened a possibility to do deposition from gas phase and at various pressure (ambient, primary vacuum, and high vacuum) of diamondoids on silicon or mica substrates. SEM observations have shown that depending on the type of functional groups on the diamondoid, different crystal shapes can be produced (rods, needles, triangles, truncated octahedral form).OMCVD of palladium on functionalized diamantanes showed that Pd deposition occurs preferentially on the oxide native layer on silicon substrates than on diamondoid crystals bearing hydroxyl or fluorine groups. This urged the synthesis new diamondoids with phosphino groups in order to make strong covalent bonding between the modified diamondoid and palladium.A full set of functionalized diamondoid phosphines were synthesized with unexpected air-stability of some primary diamondoid phosphines were observedIt has been shown that the use of P(III) phosphine as anchoring sites allowed the formation of hybrid material Pd@PH2-Diam-OH. Different characterizations (XPS, SEM, TEM, and EDX) indicated that an insulator material Pd@PH2-Diam-OH formed during the CVD deposition with P–Pd interaction.

OMCVD de palladium

Pd OMCVD

Hybrid material

Functionalized diamondoid

Organic self-assembly

Air-stable phosphine

547

Synthèse, caractérisation et mise en œuvre d’un matériau hybride organique-inorganique photosensible de type résine positive : application à la fabrication de dispositifs de microfuidique par écriture Laser / Synthesis, characterization and implementation of a hybrid organic-inorganic photosensitive resin positive : application to the manufacture of devices by writing laser microfuidique

Mechref, Elias

11 December 2015

Depuis quelques décennies, les matériaux composites organique/inorganique font l’objet de nombreux travaux de recherches. En raison de leurs propriétés uniques et intermédiaires entre les deux mondes minérales et organiques, ces matériaux sont d’un grand intérêt pour des nombreuses applications tel que le domaine, d’optique, la microfluidique, la microélectronique…, La synthèse de ce type des matériaux est réalisée à moindre coût en deux étapes : La synthèse du réseau inorganique est effectué par procédé sol-gel , tant qu’à la partie organique des compositions de type résines négatives et positives possède la particularité d’être photo-réticulables sous irradiation (UV et visible). Parallèlement, est apparue la lithographie par écriture laser (spot de quelques microns). Elle s’avère très pertinente pour la mise au point d’un procédé pour lequel des objets de petites dimensions (quelques Microns) et de petites surfaces sont à réaliser car elle permet de s’affranchir de la fabrication de masques. Cette technique associée aux résines négatives, n’est pas idéale pour la fabrication d’objets de grandes surfaces en raison de temps de fabrication induits trop long. Il est, par exemple, extrêmement compliqué et couteux d’utiliser l’écriture Laser pour la réalisation de dispositifs microfluidiques. En effet, la création de canaux de taille micronique nécessite une très grande surface à insoler. Il est donc bien plus pertinent de travailler sur l’association de l’écriture laser avec une résine de type positive. L’objectif principal de ce travail est la synthèse, l’optimisation et mise en œuvre d’un matériau hybride photosensible de type résine positive : Application à la fabrication des capteurs microfluidiques. Notre choix s’est porté sur le poly(amic acid) PAA de masse molaire 2340 g/mol comme partie organique, connu pour ces bonnes propriétés mécaniques et sa grande stabilité thermique. Le travail est centré d’une part, sur la synthèse d’une résine positive photosensible à la longueur d’onde utilisée (365 nm) à base du polymère PAA. En général, les PAA sont très solubles dans une solution alcaline aqueuse, dû à la présence d’acide carboxylique. Afin d’améliorer le contraste entre la partie insolée et non insolée après le développement, un inhibiteur de dissolution 1,3,5-tris[(2-vinyloxy)ethoxy]benzène (TVEB) est greffé au PAA via la fonction vinyl éther. Ce dernier permet la réduction de la teneur en acide carboxylique dans le motif répétitif du polymère et comme conséquence diminuer la dissolution de la partie non insolée. D’autre part, la synthèse du matériau hybride à base de la résine photosensible optimisée, est réalisée par greffage d’un précurseur ORMOSIL le 4-vinyléther-phenyltriéthoxysilane (VEPTES) pré-hydrolysé par procédé sol-gel comme partie inorganique à notre polymère. Afin d'optimiser le matériau, une étude structurale a été réalisée depuis la synthèse du solution jusqu'à l'obtention des dépôts et enfin la création des canaux microfluidiques. Une amélioration significative au niveau des propriétés mécaniques et thermiques est notée au niveau du polymère par ajout d’une partie minérale. / In recent decades, the organic / inorganic composite materials are the subject of many research works. Because of their unique properties and intermediate between inorganic and organic worlds, these materials are of great interest for many applications such as the area, optical, microfluidics, microelectronics ... The synthesis of this type of materials is carried out at a lower cost in two stages: The synthesis of inorganic network is made by sol-gel process, as well as the organic part of the negative and positive resin type compositions has the particularity of being photo-crosslinked under irradiation ( UV and visible).Meanwhile, the lithography by laser writing has appeared (spot a few microns). It is particularly appropriate for the development of a method for which small objects (a few microns) and small surfaces are to achieve because it eliminates the production of masks. This technique associated with negative resins, is not ideal for manufacturing large objects surfaces due to induced production time too long. It is, for example, be extremely complicated and expensive to use writing laser for producing microfluidic devices. Indeed, the creation of micron-sized channels requires a very large surface area to be exposed. It is therefore more appropriate to work on the combination of laser writing with a resin positive type. The main objective of this work is the synthesis, optimization and implementation of a photosensitive hybrid material resin positive type: Application to the fabrication of microfluidic sensors. Our choice fell on the poly(amic acid) PAA with molar mass of 2340 g/mol as an organic part, known for its good mechanical properties and high thermal stability.The work focuses on a part, on the synthesis of a positive photosensitive resin at the wavelength used (365 nm) based on the PAA polymer. In general, PAA are very soluble in an aqueous alkaline solution, due to the presence of carboxylic acid. In order to improve the contrast between the irradiated and unirradiated part after the development, an dissolution inhibitor 1,3,5-tris [(2-vinyloxy) ethoxy] benzene (TVEB) is grafted to the PAA via the vinyl ether function. This allows the reduction of the carboxylic acid content in the repeating unit of the polymer and as a consequence reduces the dissolution of the non-exposed part.On the other part, the synthesis of the hybrid material based on the optimized photosensitive resin is formed by grafting a precursor ORMOSIL 4-vinylether-phenyltriethoxysilane (VEPTES) pre-hydrolyzed by sol-gel method as the inorganic part to our polymer. In order to optimize the material, a structural study was conducted for the synthesis of the solution until the deposits and the creation of microfluidic channels. A significant improvement in mechanical and thermal properties is recorded at the polymer by adding an inorganic portion.

Dispositif microfluidique

Résine positive

Materiau hybride organique-inorganique

Microfluidic device

Resin positive

Organic-Inorganic hybrid material