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Funkcionalizace polyolefinů roubováním / Functionalization of polyolefins by graftingPaulenka, Igor January 2017 (has links)
The theoretical part of the diploma thesis is focused on the funcionalization of polyolefins in order to accelerate their degradation and to increase their carbon content from renewable resources with focus on hydroxyacids. The experimental part is focused on preparing samples and studying the properties of the polypropylene and polyethylene blends with the polylactide with different contents of the initiator and the maleic anhydride. Samples were evaluated by determining the degree of conversion maleic anhydride, differential scanning calorimetry, infrared spectroscopy, melt flow index and mechanical properties.
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Bioactive coatings to control marine biofoulingTasso, Mariana Patricia 12 November 2009 (has links)
The colonization of immersed surfaces by a myriad of marine organisms is a complex, multi-stage, species-specific process giving rise to economic and environmental costs. This unwanted accumulation of organisms in the marine environment, called biofouling, has been attacked from different fronts, going from the ‘problem-elimination-as-problem-solving’ strategy (essentially through the use of biocides) to more elaborated and environmentally-friendly options based on the principle of ‘non-stick’ or ‘easy foul-release’ surfaces, which do not jeopardize marine life viability. Several marine organisms rely on proteinaceous adhesives to secure a holdfast to surfaces. Proteolytic enzymes have been demonstrated to be effective agents against settlement and settlement consolidation onto surfaces of marine bacteria, algae, and invertebrates, their proposed mode-of-action being the enzymatic degradation of the proteinaceous components of the adhesives. So far, however, the evidence remains inconclusive since most of the published investigations refer to commercial preparations where the enzyme is mixed with other components, like additives, which obviously act as additional experimental variables.
This work aims at providing clear, conclusive evidence about the potential of serine proteases to target the adhesives produced by a group of model marine biofoulers. The strategy towards the goal consisted in the preparation and characterization of maleic anhydride copolymer nanocoatings modified by a surface-bound enzyme, Subtilisin A, the active constituent of the commercial preparations reported as effective against biofouling. The enzyme-containing maleic anhydride copolymer films were characterized (enzyme surface concentration, activity, stability, roughness and wettability) and thereafter tested in biological assays with three major biofoulers: spores of the green alga Ulva linza, cells of the pennate diatom Navicula perminuta, and cyprid larvae of the barnacle Balanus amphitrite. The purpose of the biological assays was to elucidate the efficacy of the immobilized catalyst to discourage settlement and/or to facilitate removal of these organisms from the bioactive layers. Results confirmed the initial hypotheses related to the enzymatic degradation of the biological adhesives: the immobilized protease was effective at reducing the adhesion strength of Ulva spores and Navicula diatoms in a manner that correlated with the enzyme activity and surface concentration, and deterred settlement of Balanus amphitrite barnacle cyprids even at the lowest surface activity tested. By facilitating the removal of biofilm-forming diatoms and of spores of the troublesome alga Ulva linza, as well as by interfering with the consolidation of adhesion of the calcareous Balanus amphitrite macrofouler, the enzyme-containing coatings here disclosed are considered to constitute an appealing and promising alternative to control marine biofouling without jeopardizing marine life.
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Substratinduzierte Differenzierung von EndothelzellenHerklotz, Manuela 24 June 2008 (has links)
Der Erfolg neuer Strategien in der Regenerativen Medizin und im Tissue Engineering hängt maßgeblich von einem gut entwickeltem vaskulären Netzwerk ab, welches die auf den Implantaten wachsenden Zellen und Gewebe versorgen. Oberflächeneigenschaften der Implantate sowie die Präsentation verschiedener Liganden für extrazelluläre Matrixproteine spielen bei der Besiedlung der Implantate, als auch bei der Bildung versorgender Blutgefäße durch die Endothelzellen eine wesentliche Rolle. In dieser Arbeit konnte durch Variation der Anbindungsstärke (kovalent oder physisorptiv) des extrazellulären Matrixproteins Fibronektins an die MSA-Copolymere der Einfluss des Aufbaus der extrazellulären Matrix auf das Differenzierungsverhalten der Endothelzellen gezeigt werden. Auch die initiale Konzentration von Adhäsionsproteinen an der Substratoberfläche zeigte sich bedeutend für das Verhalten der Zellen. Optimal für eine gute Adhäsion, native Entwicklung und Kapillarbildung der Endothelzellen war die stabile (kovalente) Anbindung weniger Adhäsionsproteine (hier Fibronektin) an die Substratoberfläche, so dass die Zellen problemlos adhärieren konnten. Erfolgte die weiter Proteinadsorption an die Oberflächen in einem nativen Zustand (hier auf den hydrophilen Oberflächen) so waren die Endothelzellen in der Lage, die extrazelluläre Matrix zu reorganisieren und ein dem in vivo Zustand ähnlicher Aufbau der extrazellulären Matrix konnte realisiert werden. Dies ermöglichte den Zellen wiederum ein natürliches Verhalten. Die Ausbildung einer moderaten Anzahl von Adhäsionsstellen der Zellen, sowie der in vivo ähnliche Aufbau der Adhäsionspunkte ermöglichte den Zellen einen eher lockeren Kontakt zum Substrat. Daher waren sie sehr flexibel in ihrer Morphologieanpassung. Unter diesen Bedingungen war es möglich, dass die Endothelzellen bei Stimulierung der Angiogenese kapillarähnliche Strukturen ausbildeten. Die Verwendung dreidimensionaler Zellkulturträger zeigte eine Unterstützung der Kapillarbildung der Endothelzellen in Abhängigkeit unter den beschrieben Bedingungen. / The success of tissue engineering strategies using artificial scaffolds crucially depends on a controlled formation of well-developed vascular networks in growing tissues. The presentation of extracellular matrix ligands on scaffolds is often envisioned as an appropriate strategy to support capillary formation. We show that the control of primary coupling mode — covalent versus physisorbed — as well as of secondary interactions of cell-secreted extracellular matrix proteins have a strong impact on endothelial cell development. A set of maleic anhydride copolymer thin films was used as planar model substrates. They exhibit a switchable mode of primary matrix coupling combined with a gradation of secondary matrix–substrate interactions due to a variation of surface hydrophobicity and polarity. We found that the cells adhere in a more native state at a low amount of covalent primary coupled fibronectin ligands in conjunction with weak interactions of secondarily adsorbed adhesion ligands on hydrophilic surfaces. These substrates allow for a formation of capillary-like networks of endothelial cells. High ligand densities and strong secondary hydrophobic interactions inhibit a pronounced capillary formation. The composition and structure of the formed extracellular matrix correlates well with the specific integrin expression pattern. From these results it is concluded that the formation of blood capillaries in artificial scaffolds can be triggered by controlling primary and secondary coupling of cell adhesion ligands to implant materials. 2
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Aprovechamiento integral del Cannabis sativa como material de refuerzo/carga del polipropilenoVallejos, María Evangelina 09 June 2006 (has links)
En este trabajo se ha estudiado el potencial tanto los filamentos de cáñamo como de la cañamiza como refuerzo/carga del polipropileno. La modificación de estos materiales se realiza para lograr una mayor compatibilidad con la matriz polimérica. Se evaluaron las propiedades mecánicas de las resistencias a tracción e impacto, de los materiales compuestos reforzados tanto de filamento como de cañamiza. Los filamentos de cáñamo poseen suficiente capacidad de refuerzo en los materiales compuestos basado en polipropileno debido a sus propiedades intrínsecas, siendo una buena alternativa como material de refuerzo. Así, la adición de MAPP (polipropileno modificado con anhídrido maleico) conduce a materiales compuestos con unas resistencias a tracción de hasta el 70% de las que se obtienen con compuestos de PP reforzados con fibra de vidrio. Mientras que la cañamiza ha actuado como una carga en la matriz, incrementado significativamente la rigidez de los materiales compuestos. / In this work, the potential of hemp strands as well as hemp straw, to be used as reinforcement/filler of polyprppylene has been studied. The modification of these materials ha been carried out to obtain a greater compatibility with the polymer matrix. The mechanical properties of the obtained materials were evaluated under tensile, flexural and impact stresses. The hemp strands showed a sufficient capacity of reinforcement in the polypropylene-based composite due to their intrinsic properties, being a good alternative like reinforcement agent. Thus, the addition of MAPP (polypropylene modified with maleic anhydride) leaded to composites with a value of ultimate tensile strength that achieved 70% of the value of materials formulated with PP and fibreglass. In the particular case of the addition of hemp straw, this component acted as a filler of the polymer matrix, increasing the rigidity of the composite but with a limited influence in the ultimate tensile strength.
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The influence of reactive modification on the compatibility of polyolefins with non-olefinic thermoplasticsLim, Henry C. A. January 2011 (has links)
Polyethylene (PE) resins being non-polar in nature and having a high degree of crystallinity have limited miscibility and compatibility when blended with polar polymers. The miscibility and compatibility of these blends are generally worsened when they are prepared by direct injection moulding without a precompounding process. Such situations are commonly encountered in particular by polymer converters when blending colour and/or additive concentrates, commonly known as masterbatches. Typically, masterbatches are mixtures containing high loading of pigments and/or additives predispersed in a suitable solid vehicle (commonly known as carrier) such as a polyethylene resin. These masterbatches are usually used for the colouration of a wide range of polymers and the carrier used must therefore be compatible with these matrix (host) polymers. The preliminary stage of this study involved the investigation of the properties of blends based on high density polyethylene (HDPE) and a range of engineering thermoplastics (ABS, PC, PBT, PA6), prepared by injection moulding. Five different types of compatibilisers namely, ethylene-vinyl acetate (EVA) copolymer, ethylene-methyl acrylate (EMA) copolymer, ethylene-glycidyl methacrylate (E-GMA) copolymer, ethylene-methyl acrylateglycidyl methacrylate (E-MA-GMA) terpolymer and maleic anhydride grafted HDPE (HDPE-g-MAH) copolymer were evaluated with respect to their efficiencies in compatibilising HDPE with the four engineering polymers. The pre-compounded HDPE/compatibiliser binary blends at 2 different blend ratios (1:1 and 3:1) were added at 15 wt% concentration to each engineering thermoplastics and test samples were produced directly by injection moulding. Results of mechanical testing and characterisation of the blends showed that glycidyl methacrylate compatibilisers, E-MA-GMA, in particular have the most universal compatibilising effectiveness for a range of engineering thermoplastics including ABS, PC, PBT, and PA6. Blends compatibilised with E-MA-GMA compatibiliser had the best notched impact performance irrespective of matrix polymer type. The presence of an acrylic ester (methyl acrylate) comonomer in E-MA-GMA resulted in increased polarity of the ii compatibiliser leading to improved miscibility with the polar matrix polymers demonstrated by fine blend morphologies, melting point depression and reduction in crystallinity of the HDPE dispersed phase. The second stage of this study involved the reactive modification of HDPE using a low molecular weight di-functional solid diglycidyl ether of bisphenol A (DGEBA) type epoxy resin compatibilised with HDPE-g-MAH in an attempt to improve its compatibility with ABS, PBT and PA6. The maleic anhydride moieties in HDPE-g-MAH served as reactive sites for anchoring the epoxy moieties while the HDPE backbone was miscible with the HDPE resin. An excessive amount of reactive groups resulted in the formation of crosslinked gels while the addition of EVA co-compatibiliser helped in the reduction of gel content and further improved the dispersion of the epoxy. The effectiveness of epoxy grafted HDPE (with and without EVA co-compatibiliser) in compatibilising ABS/HDPE, PBT/HDPE, and PA6/HDPE was investigated by injection moulding of 5 wt% functionalised HDPE with these matrix polymers into test bars for mechanical testing, and characterisation by differential scanning calorimtery (DSC) and optical microscopy. The reactively functionalised HDPE blends, improved the mechanical properties of ABS and PA6 blends especially with EVA as co-compatibiliser. However, the mechanical properties of PBT blends were unmodified by the functionalised HDPE which was believed to be due to end-capping of the PBT chain-ends by ungrafted epoxy resins.
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Structuration de nanocomposites à partir de copolymères à blocs : expérience et modélisation / Structuring nanocomposites from copolymers block : experience and modelingPeng, Zhen 27 February 2012 (has links)
Les copolymères à blocs sont des matériaux très intéressants en raison de leur capacité à s’auto-organiser pour former des domaines de quelques dizaines de nanomètres. Cette organisation peut être mise à profit pour obtenir des matériaux hybrides organiques/inorganiques dans lesquels la phase inorganique peut être structurée dans un des domaines plutôt que répartie de façon aléatoire. Ceci peut conférer des propriétés particulières aux copolymères hybrides. Notre travail de thèse s’inscrit dans cette problématique. Des copolymères à blocs ont été modifiés soit par greffage en solution de molécules organiques/inorganiques du type POSS réactif (polyhedral oligomeric silsesquioxane), soit par mélange en solution ou à l’état fondu de POSS non réactif. Les copolymères triblocs considérés sont du type SBS (styrène-butadiène-styrène) et SEBS-g-MA (styrène-éthylène-butène-styrène greffé anhydride maléique). L’ensemble de ces copolymères a été caractérisé expérimentalement afin de déterminer leur morphologie et leur comportement thermo-mécanique. En parallèle une approche théorique a été proposée, basée sur la modélisation moléculaire de ces copolymères à l’échelle mésoscale. La méthode sélectionnée ‘Dissipative Particle Dynamics’ a permis de modéliser la morphologie de nos copolymères avec succès ainsi que celle de nos matériaux hybrides modifiés par les POSS. Ces derniers peuvent être dispersés à l’échelle moléculaire ou au contraire former des agrégats, selon le procédé de mise en œuvre et la structure chimique des POSS. / Experimental approaches and a modeling method have been carried out in parallele. The simulation method was used firstly to confirm the experimental results, and then will be applied to more complex nanocomposites. A series of hybrid systems based on triblock copolymer of polystyrene-butadiene-polystyrene (SBS) grafted with polyhedral oligomeric silsesquioxane(POSS) molecules with a dimethylsiloxy group (DMIPOSS) were synthesized by a hydrosilation method. The characteristics on incorporation of an unreactive POSS with constituent cyclohexyl (CyPOSS) in SBS matrix have been compared with above systems. The nanocomposites obtained were analyzed by atomic force microscopy, Transmission electron microscopy, X-ray scattering and dynamic mechanical.The same strategy has been carried out on polystyrene-b-poly (ethylene-co-butylene)-b-polystyrene-g-maleic anhydride (SEBS-g-MA) with other type of POSS. Dynamic particles dissipative (DPD) simulation methods in Materials Studio (Accelrys) were employed to study morphology of SB, SBS, SEBS and hybrid system. In this mesoscopic method, the polymer is simplified as a series of connecting beads which contains one or more monomer units. And all monomer units interact with each other following Newtonian Equations of Motion.
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Dual-Component Gelatinous Peptide/Reactive Oligomer Formulations as Conduit Material and Luminal Filler for Peripheral Nerve RegenerationKohn-Polster, Caroline, Bhatnagar, Divya, Woloszyn, Derek J., Richtmyer, Matthew, Starke, Annett, Springwald, Alexandra H., Franz, Sandra, Schulz-Siegmund, Michaela, Kaplan, Hilton M., Kohn, Joachim, Hacker, Michael C. 21 December 2023 (has links)
Toward the next generation of nerve guidance conduits (NGCs), novel biomaterials and
functionalization concepts are required to address clinical demands in peripheral nerve regeneration
(PNR). As a biological polymer with bioactive motifs, gelatinous peptides are promising building
blocks. In combination with an anhydride-containing oligomer, a dual-component hydrogel system
(cGEL) was established. First, hollow cGEL tubes were fabricated by a continuous dosing and
templating process. Conduits were characterized concerning their mechanical strength, in vitro
and in vivo degradation and biocompatibility. Second, cGEL was reformulated as injectable shear
thinning filler for established NGCs, here tyrosine-derived polycarbonate-based braided conduits.
Thereby, the formulation contained the small molecule LM11A-31. The biofunctionalized cGEL filler
was assessed regarding building block integration, mechanical properties, in vitro cytotoxicity, and
growth permissive effects on human adipose tissue-derived stem cells. A positive in vitro evaluation
motivated further application of the filler material in a sciatic nerve defect. Compared to the empty
conduit and pristine cGEL, the functionalization performed superior, though the autologous nerve
graft remains the gold standard. In conclusion, LM11A-31 functionalized cGEL filler with extracellular
matrix (ECM)-like characteristics and specific biochemical cues holds great potential to support PNR.
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Recycling of Glass Fiber CompositesKrishnamoorthi, Ramesh, Shinzhao, Zhang January 2012 (has links)
Composites are the materials which can be used for a wide variety of applications andproducts such as sports equipment, aerospace and marine because of light and stiffnessproperties. Composites are often made from thermoset resin with glass fibers.In this study, two ways of recycling composites were evaluated, which are microwavepyrolysed composites (MGC) and mechanical composites (GC). These glass fibers weregoing to be compounded with Polypropylene (PP) or Maleic Anhydride ModifiedPolypropylene (MAPP) and then injection moulded the sample by Micro-compounder.In order to get better adhesion to the polymer, a coating was added. The Neoxil 5682-polypropylene water emulsion was evaluated.The samples were characterized by Tensile Testing, Thermogravimetric Analysis (TGA),Different Scanning Calorimetry (DSC), and Dynamic Mechanical Analysis (DMA) to find aoptimum combination of recycled glass fiber reinforced polymer.Microwave pyrolysis is a new research area. The glass fiber, polymer oil and gas can beobtained by heating the composite with microwaves to in an inert atmosphere. The polymeroil can be distillated and then evaluated with GC-MS; in order to obtain the chemicalcompositions.Keywords: Composites, grinded and microwave pyrolyse composites (MGC), grindedcomposites (GC), Polypropylene (PP), Maleic Anhydride Modified Polypropylene (MAPP),Micro-compounder, Tensile Testing, Thermogravimetric Analysis (TGA), Different ScanningCalorimetry (DSC), and Dynamic Mechanical Analysis (DMA), Microwave pyrolysis,polymer oil, distillation, GCMS Analysis. / Program: MSc in Resource Recovery - Sustainable Engineering
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Single-Step Covalent Functionalization of Polylactide Surfaces / Nano Patterened Covalent Surface Modification of Poly(ε-caprolactone)Källrot, Martina January 2005 (has links)
<p>Degradable polymers have gained an increased attention in the field of biomedical applications over the past decades, for example in tissue engineering. One way of improving the biocompatibility of these polymers is by chemical surface modification, however the risk of degradation during the modification procedure is a limiting factor. In some biomedical applications, for example in nerve guides, a patterned surface is desired to improve the cell attachment and proliferation.</p><p>In this thesis a new non-destructive, single-step, and solvent free method for surface modification of degradable polymers is described. Poly(L-lactide) (PLLA) substrates have been functionalized with one of the following vinyl monomers; N-vinylpyrrolidone (VP), acrylamide (AAm), or maleic anhydride (MAH) grafts. The substrates were subjected to a vapor phase atmosphere constituted of a mixture of a vinyl monomer and a photoinitiator (benzophenone) in a closed chamber at very low pressure and under UV irradiation. Poly(ε-caprolactone) (PCL), poly(lactide-co-glycolide) (PLGA), and poly(trimethylene carbonate) (PTMC) have been surface modified with VP using the same procedure to show the versatility of the method. The wettability of all of the four substrates increased after grafting. The surface compositions were confirmed by ATR-FTIR and XPS. The VP grafted PLLA, PTMC and PLGA substrates have been shown to be good substrates for the normal human cells i.e. keratinocytes and fibroblasts, to adhere and proliferate on. The topography of substrates with well defined nano patterns was preserved during grafting, since the grafted layer is very thin. We have also shown that the method is useful for a simultaneous chemical and topographical modification of substrates by masked vapor phase grafting. The surface topography was determined with SEM and AFM.</p> / <p>Intresset för användningen av nedbrytbara polymerer till biomedicinska applikationer som till exempel vävnads rekonstruktion har ökat avsevärt de senaste decennierna. Ett sätt att öka biokompatibiliteten hos dessa polymerer är genom kemisk ytmodifiering, men risken för nedbrytning under själva modifieringen är en begränsande faktor. I vissa biomedicinska applikationer, till exempel nervguider, är det önskvärt att ha en väldefinierad ytstruktur för att öka vidhäftningen och tillväxten av celler.</p><p>I den här avhandlingen presenteras en ny ickeförstörande, lösningsmedelsfri enstegsprocess för ytmodifiering av nedbrytbara polymerer. Substrat av poly(L-laktid) (PLLA) har ytfunktionaliserats med var och en av följande vinylmonomerer, N-vinylpyrrolidon (VP), akrylamid (AAm) eller maleinsyraanhydrid (MAH). Substraten har exponerats för en gasfasatmosfär av en blandning av en vinylmonomer och en fotoinitiator (bensofenon) i en tillsluten reaktor vid mycket lågt tryck och under UV-strålning. Metodens mångsidighet har även påvisats genom att ytmodifiera substrat av poly(ε-kaprolakton) (PCL), poly(laktid-co-glykolid) (PLGA) och poly(trimetylen karbonat) (PTMC) med VP. Vätbarheten ökade för alla fyra materialen efter ympning med en vinylmonomer. Ytsammansättningen fastställdes med ATR-FTIR och XPS. De VP ympade filmerna av PLLA, PLGA och PTMC visade sig vara bra substrat för mänskliga celler, i detta fall keratinocyter och fibroblaster, att vidhäfta och växa på. Yttopografin hos filmer med väldefinierade nanomönstrade ytor kunde bevaras efter ympning, tack vare att det ympade lagret är så tunt. Gasfas metoden har också visat sig användbar för att simultant ytmodifiera både kemiskt och topografiskt genom maskad gasfasympning. Yttopografin bestämdes med SEM och AFM.</p>
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Comportements thermomécaniques de polymères chargés selon différents chemins de déformation et traitements thermiques / Thermomechanical behaviours of filled polymers along various deformation paths and thermal treatmentsPonçot, Marc 28 October 2009 (has links)
Le centre de recherche ArcelorMittal de Montataire développent de nouvelles solutions acier innovantes associant métal et polymère. Pour les ailes de voiture, le composite retenu est un matériau multicouche composé d’une lame d’acier sur laquelle est déposé un film mince de polypropylène choc chargé avec des particules minérales par l’intermédiaire d’une fine couche de polypropylène fonctionnalisé par le greffage d’anhydride maléique. Afin de prévoir et de connaitre le comportement de la partie organique du matériau lors de sa mise en forme par emboutissage et à posteriori de prédire l’état de ses propriétés mécaniques lors de son utilisation, la détermination des lois de comportement mécanique vrai et intrinsèque sur le modèle de la loi G’sell et Jonas est nécessaire. Ces lois sont définies selon trois chemins de déformation : la traction uniaxiale, le cisaillement simple et la traction plane. Les micromécanismes de déformation de la microstructure semi-cristalline des différentes formulations des matériaux selon leur mode de sollicitation mécanique ont été étudiés. Les résultats obtenus Post Mortem et In Situ ont permis la description qualitative et quantitative des évolutions des principales modifications microstructurales. Ces dernières diffèrent avec l’ajout de charges minérales. Deux nouvelles méthodes, la Tomographie X et la spectroscopie Raman permettent la détermination de la déformation volumique dans le cas de matériau de géométrie fine (300 µm). Le retrait lors d’un cycle thermique est étudié. Les influences du chauffage, de la formulation et de la microstructure (orientation des chaînes macromoléculaires et endommagement volumique) sont décrites / The ArcelorMittal research centre of Montataire elaborates innovative steel / polymer products. In the case of automotive fenders, the composite is a multilayered material. A thin impact polypropylene film is laminated on steel using a thin layer of a functionalized polypropylene. Mineral particles are added to improve stiffness. In order to predict and understand the behaviour of the organic layer all along its production process and finally to be able to characterize the state of its mechanical properties in use, the determination of the true and intrinsic mechanical behaviour laws according to the G’sell and Jonas model is necessary. These laws are obtained for three different mechanical paths: uniaxial tensile, simple shear and plane tensile. The deformation micromechanisms of the impact polypropylene semi-crystalline microstructure which depend on the materials formulations and on the mechanical path used are studied. Post Mortem and In Situ results give qualitative and quantitative description of the main microstructural modifications. Two new methods, X Tomography and Raman spectroscopy allow the quantification of the volume deformation which is developed during tensile tests. They are mainly available for very thin samples. X radiography and VideoTraction™ are not suitable anymore for this kind of geometry. Finally, the thermo-mechanical phenomenon of shrinkage which occurs during thermal treatment above the material melting point is analysed. Influences of the heating conditions, of the material formulations and of the material microstructure are described. Special overviews are done on the macromolecular chains orientation and on the volume damage influences
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