Compréhension des phénomènes interfaciaux dans les composites à base de charges carbonate de calcium précipité : influence du traitement de surface et du procédé de mise en œuvre / Interfacial behaviour comprehension in polymer / calcium carbonate composite : effect of surface treatment and processing of composites

Morel, Floriane

10 December 2010

Ce travail a eu pour objectif la création de matériaux composites à base de nanocharges de carbonate de calcium. L'étude des phénomènes interfaciaux qui régissent ces systèmes, ainsi que leurs impacts sur les propriétés fonctionnelles du matériau et plus particulièrement des propriétés de transport, ont été réalisées. Pour ce faire, nous avons considéré deux matrices polymères de nature chimique différente : le polylactide et le polyfluore de vinylidène. Les nanocomposites ont été élaborés par deux voies de mise en œuvre : la voie fondu et la voix solvant. Une analyse fine des relations structure/morphologie/propriétés des composites a été réalisée. Nous avons mis en évidence, quelle que soit la matrice polymère choisie, l'importance du traitement de surface des charges afin d'améliorer leurs états de dispersion dans le matériau et d'augmenter la qualité de l'interface charge/polymère. Ces paramètres ont été corrélés aux propriétés de transport de ces matériaux composites. / The aim of this PhD work is to elaborate composites based on calcium carbonate nanoparticles. Polylactide and polyvinylidene fluoride were used as polymer matrix and nanocomposite were elaborated either by melting process and either by casting method. The interfacial behaviour between polymer and calcium carbonate were studied and we especially focused on their impact on the composite gas barrier properties. The importance of filler surface treatment had been highlighted on the filler dispersion state improvment and filler/polymer interface reinforcement. Both parameters were important in the improvement of composite gas barrier properties.

Carbonate de calcium

Poly(lactide)

Poly(fluorure de vinylidène)

Composite

Propriétés de transport aux gaz

Interfaces

Calcium carbonate

Poly(lactide)

Poly(vinylidene foluoride)

Composite

Gas transport properties

Interfaces

620.11

Experimental Study Of Profiles Of Implanted Species Into Semiconductor Materials Using Secondary Ion Mass Spectrometry

Salman, Fatma

01 January 2007

The study of impurity diffusion in semiconductor hosts is an important field that has both fundamental appeal and practical applications. Ion implantation is a good technique to introduce impurities deep into the semiconductor substrates at relatively low temperature and is not limited by the solubility of the dopants in the host. However ion implantation creates defects and damages to the substrate. Annealing process was used to heal these damages and to activate the dopants. In this study, we introduced several species such as alkali metals (Li, Na, K), alkali earth metals (Be, Ca,), transition metals (Ti, V, Cr, Mn) and other metals (Ga, Ge) into semiconductor substrates using ion implantation. The implantation energy varies form 70 keV to 200 keV and the dosages vary between ~ 1.0x1012 and ~5.0x1015 atoms/cm2. The samples are annealed at different temperatures from 300°C to 1000°C and for different time intervals. The redistribution behaviors of the implanted ions are studied experimentally using secondary ion mass spectrometry (SIMS). We observed some complex distribution behaviors due to the defects created during the process of ion implantation. The diffusivities of some impurities are calculated and compared to previous data. It was found that the diffusivities of implanted impurities is related to the dosages, annealing temperatures and the defects and damages caused by ion implantation. Additionally, as we go from one type of semiconductor to another, the diffusion behavior of the impurities shows a different trend.

Diffusion

Si

Poly-Si

GaN

TaSi2

Physics

Poly-Silicon Passivating Contacts for Crystalline Silicon Solar Cells

Alzahrani, Areej A

14 December 2021

Passivating-contact technologies fabricated from polycrystalline-silicon (poly-Si) are increasingly considered by the crystalline silicon (c-S) PV industry to be key enablers towards record performance. This is largely thanks to their ability to provide excellent carrier collection and surface passivation, while being compatible with industrial scale production. Poly-Si based passivating contacts consist of a stack of an ultrathin silicon oxide (SiOx) film on the surface of crystalline silicon (c-Si), covered by a doped silicon film. Thin films of SiOx can be grown by several different methods: chemically, thermally, or via UV-ozone exposure. However, each of these methods presents challenges towards industrial implementation. Here, we report an alternative method to grow SiOx films using an in-situ plasma process, where we subsequently deposit the doped poly-Si layer in the same process chamber by plasma enhanced chemical vapor deposition (PECVD). This process presents several advantages, such as ease of fabrication, inherently single-side oxide growth and poly-Si deposition, and the combined deposition in one chamber, lowering capital expenditure. Subsequently, we studied the structure of the SiOx films and the doped poly-Si(p+) capping layers using X-ray photoelectron spectroscopy (XPS) and ultraviolet photoelectron spectroscopy (UPS) in order to determine the films’ elemental composition, and the band alignment at the semiconductor/oxide interfaces. A less p-type polysilicon was observed grown on top of a wet SiOx/c-Si with the origin tentatively attributed to depletion of the boron dopant via pin holes evidenced by AFM. A surface photo-voltage (SPV) was observed by XPS under in-situ light bias (AM 1.5) and a representation of the band alignment of the c-Si/SiOx/p-polysilicon under illumination is derived. The SPV was attributed to the photo accumulation of holes at the p-polysilicon and a splitting of quasi-fermi levels with its magnitude correlated to the device measured iVoc . Finally, a valuable application for this contact technology is the integration of silicon with perovskite solar cells, in the so-called monolithic tandem configuration. This approach is very promising to develop a new generation of PV with unmatched performances. Here, poly-Si contacts offer a variety of advantages, thanks to their broader material selection and to the stability at high processing temperature.

Poly-Silicon

Passivating Contacts

Solar Cells

Double Integrating Sphere Characterization of PVA-Cryogels

Fiee, Peter Q

26 January 2015

Proper functioning of instruments requires precise calibration and routine quality assurance. In a clinical setting, this is achieved through the use of phantoms, which mimic the physical characteristics of tissues. Polyvinyl alcohol (PVA), a non-toxic, water-soluble polymer is well-suited for use as clinical phantom material. Through successive freezing and thawing, solutions of PVA in water can be solidified into rigid cryogels (PVA-C). The number of freeze-thaw cycles affects the properties of the material, including its optical characteristics. A double integrating sphere system was used in conjunction with the Inverse Adding Doubling (IAD) algorithm to characterize the optical properties of thin slab samples. The setup was evaluated using liquid phantoms. Liquid emulsion and food colouring were used to impart scattering and absorbing properties in the range characteristic of human tissue. Measured values of normalized reflectances and transmittances were entered into IAD, and a set of optical properties (μ′s,μa,g) retrieved. The reduced scattering coefficient was found to increase linearly with increasing lipid concentration, while a consistent overestimation of the absorption coefficient was observed. Measurements of PVA cryogels revealed a linear increase in the reduced scattering coefficient with an increasing number of freeze-thaw cycles up to five cycles. Scattering was also observed to increase with concentration up to PVA concentrations of 15%, and to spontaneously increase during the lifetime of the slab samples. These findings suggest it is possible to tune the optical scattering of PVA-C via different purely physical mechanisms. / Thesis / Master of Science (MSc)

Poly(vinyl alcohol)

Double Integrating Sphere Theory

Polylactide Growth on Various Oxides: Towards New Materials

Bernard, Alexandre

01 September 2010

No description available.

Chemistry

poly(lactide)

nanoparticles

materials

silica

Functional Characterization of Exopolyphosphatase/ Guanosine Pentaphosphate Phosphohydrolase (PPX/GPPA) Enzymes of Campylobacter jejuni

Kumar, Anand

17 July 2012

No description available.

Veterinary Services

ppGpp

PPX

poly-P

THE ADHESION OF POLY(DIMETHYL SILOXANE) TO SILICA SUBSTRATES

Yu, Lunquan

January 2014

The adhesion of poly(dimethyl siloxane) (PDMS) to silica substrates was measured by 90 degree peel testing of PDMS strips cast on silica substrates. The objective of this work was to investigate the effects of silica surface chemistry on the adhesion between PDMS and silica substrate. Silica substrates with different surface chemistry were prepared by both chemical modification and physical adsorption. Silane coupling agents were used to provide octyl chains and primary amino groups on the silica surfaces. Also silica surfaces were coated with cetyltrimethylammonium bromide (CTAB), polyvinylamine (PVAm) or poly(N-isopropylacrylamide) (PNIPAM) by physical adsorption. The adhesion samples were prepared by casting Sylgard® 184 silicone elastomers on silica surfaces followed by thermal curing. Water contact angle measurements, scanning electron microscopy (SEM), X-ray photoelectron spectroscopy (XPS) and Fourier transform infrared microscopy (FTIR) were performed to measure the surface properties of the peel test samples. It is believed that hydrogen bonding between siloxane bonds in PDMS and silanol groups on silica substrate contributes to the strong adhesion of PDMS and silica surface. The adhesion forces significantly reduced by the adsorption of PVAm and PNIPAM onto silica surfaces. In addition, the introduction of primary amino groups on silica surface would poison the catalyst during the curing of PDMS, which causes the formation of low crosslinking PDMS in the outer surface and is expected to decline the adhesion force. Lastly, the slightly reduce of adsorbed PVAm (340 kDa) on the silica substrate after peel test is considered to be useful for long-term lubrication. / Thesis / Master of Applied Science (MASc)

Adhesion

POLY(DIMETHYL SILOXANE)

SILICA SUBSTRATES

Preparation and Functionalization of Macromolecule-Metal and Metal Oxide Nanocomplexes for Biomedical Applications

Vadala, Michael Lawrence

28 April 2006

Copolymer-cobalt complexes have been formed by thermolysis of dicobalt octacarbonyl in solutions of copolysiloxanes. The copolysiloxane-cobalt complexes formed from toluene solutions of PDMS-b-[PMVS-co-PMTMS] block copolymers were annealed at 600-700 °C under nitrogen to form protective siliceous shells around the nanoparticles. Magnetic measurements after aging for several months in both air and in water suggest that the ceramic coatings do protect the cobalt against oxidation. However, after mechanical grinding, oxidation occurs. The specific saturation magnetization of the siliceous-cobalt nanoparticles increased substantially as a function of annealing temperature, and they have high magnetic moments for particles of this size of 60 emu g⁻¹ Co after heat-treatment at temperatures above 600 °C. The siliceous-cobalt nanoparticles can be re-functionalized with aminopropyltrimethoxysilane by condensing the coupling agent onto the nanoparticle surfaces in anhydrous, refluxing toluene. The concentration of primary amine obtained on the surfaces is in reasonable agreement with the charged concentrations. The surface amine groups can initiate L-lactide and the biodegradable polymer, poly(L-lactide), can be polymerized directly from the surface. The protected cobalt surface can also be re-functionalized with poly(dimethylsiloxane) and poly(ethylene oxide-co-propylene oxide) providing increased versatility for reacting polymers and functional groups onto the siliceous-cobalt nanoparticles.Phthalonitrile containing graft copolysiloxanes were synthesized and investigated as enhanced oxygen impermeable shell precursors for cobalt nanoparticles. The siloxane provided a silica precursor whereas the phthalonitrile provided a graphitic precursor. After pyrolysis, the surfaces were silicon rich and the complexes exhibited a substantial increase in Ms. Early aging data suggests that these complexes are oxidatively stable in air after mechanical grinding. Aqueous dispersions of macromolecule-magnetite complexes are desirable for biomedical applications. A series of vinylsilylpropanol initiators, where the vinyl groups vary from one to three, were prepared and utilized for the synthesis of heterobifunctional poly(ethylene oxide) oligomers with a free hydroxy group on one end and one to three vinylsilyl groups on the other end. The oligomers were further modified with carboxylic acids via ene-thiol addition reactions while preserving the hydroxyl functionality at the opposite terminus. The resulting carboxylic acid heterobifunctional PEO are currently being investigated as possible dispersion stabilizers for magnetite in aqueous media. / Ph. D.

poly(ethylene oxide)

cobalt

phthalonitrile

polysiloxane

nanoparticle

Proteomique fonctionnelle des poly(ADP-Ribose) polymerases

Moreel, Xavier

16 April 2018

L'ADN, support de l'information génétique, subit chaque jour de nombreuses attaques pouvant induire différents types de lésions. Que ce soit d'origine environnementale (agents chimiques), rayonnements ionisants) ou d'origine endogène (métabolisme de L'ADN, radicaux libres), chacun de ces agents peut provoquer des cassures simple ou double-brin dans la molécule d'ADN. Ces lésions doivent être détectées rapidement et réparées fidèlement, afin d'éviter d'engendrer une mutation pouvant déclencher une maladie telle le cancer, ou encore éviter de se transmettre à la descendance. Au cours de l'évolution, la cellule eucaryote a développé différentes voies spécifiques pour répondre à un stress génotoxique. Ainsi il existe un véritable réseau de surveillance et d'évaluation des dommages permettant à la cellule lésée de réparer l'ADN ou d'entrer en apoptose si les dommages sont trop importants. La poly(ADP-ribosyl)ation des protéines est une modification post-traductionnelle qui intervient rapidement dès qu'une cassure dans la molécule d'ADN est détectée. Le polymère est synthétisé à partir du NAD+ par une famille d'enzymes appelées PARP (poly(ADP-ribose)polymérase), dont le rôle principal est la maintien de l'intégrité du génome. Cette modification affecte les propriétés physico-chimiques ainsi que la fonction des protéines cibles. Celle-ci permet, entre autre, le recrutement des enzymes de réparation de l'ADN. Ce signal demeure toutefois transitoire, le polymère formé étant rapidement dégradé par la PARG (poly(ADP-ribose)glycohydrolase. Ce travail présente une analyse structurale de la PARP-3, un membre peu caractérisé de la famille PARP, ainsi qu'une analyse fonctionnelle de mutants de phosphorylation de la PARP-1 (premier article) qui montre que la phosphorylation du premier doigt de zinc de cette protéine altère son recrutement et sa persistance aux sites de cassure de l'ADN. Par ailleurs, de nombreuses évidences montrent que que la poly(ADP-ribosyl)ation des protéines peut survenir dans un contexte autre que les dommages à l'ADN, le second article présente les métabolismes qui peuvent être associés aux PARP-1 et 2 ainsi qu'à la PARG et monte un possible nouveau rôle biologique pour la PARP-1.

Poly (ADP-ribose) polymérase

ADN -- Réparation

Analyses biochimique et protéomique de la poly(ADP-ribosyl)ation

Tardif, Maxime

17 April 2018

La poly(ADP-ribosyl)ation est une modification post-traductionnelle qui est stimulée en réponse à des dommages à l'ADN. Les poly(ADP-ribose) polymerases (PARPs) synthétisent des polymères branchés de poly(ADP-ribose) (PAR) qui peuvent se lier de manière covalente et non-covalente à des protéines jouant ainsi un rôle dans des processus tels que la progression du cycle cellulaire, la réparation de l'ADN, la stabilité de l'intégrité génomique et l'apoptose. Le cycle de dégradation du PAR induit aussi une variation des réserves en nucleotides comme le NAD+, l'ATP et l'AMP, influençant les voies énergétiques des cellules. Les techniques de « Matrix Assisted Laser Desorption Ionisation » (MALDI) et de quantification de nucleotides par colorimétrie, fluorométrie et HPLC ont été utilisées pour déterminer de nouveaux partenaires protéiques interagissant avec le polymère d'ADPr, par l'entremise d'interaction directe, covalente et non-covalente, ou par l'entremise d'interaction indirecte, via le cycle de synthèse/dégradation du PAR qui induit d'importants changements métaboliques cellulaires.

Poly (ADP-ribose) polymérase

ADP-ribosylation