Global ETD Search

851	PROBING POLYMER DYNAMICS USING HIGH THROUGHPUT BROADBAND DIELECTRIC SPECTROSCOPY Xiao, Zhang 01 October 2018 (has links) No description available. Polymer Chemistry Polymers Chemical Engineering Chemistry Polymer Dynamics Interfacial Confinement Polymer Glass Transition Polymer Nanocomposites Dielectric Spectroscopy High Throughput Characterization
852	Extensional Mixing Elements for Improved Dispersive Mixing in Extrusion Operations Pandey, Vivek 07 September 2020 (has links) No description available. Engineering Fluid Dynamics Polymers Plastics Extruder dispersive mixing computational fluid dynamics ansys polyflow morphology polymer blends nanocomposites
853	Viscoelastic Characterization of Vapor-Grown Carbon Nanofiber/Vinyl Ester Nanocomposites using a Response Surface Methodology Drake, Daniel Adam 11 May 2013 (has links) The effects of vapor-grown carbon nanofiber (VGCNF) weight fraction, applied stress, and temperature on the viscoelastic responses (creep strain, creep rate, and creep compliance) of VGCNF/vinyl ester (VE) nanocomposites were studied using a central composite design (CCD). The nanocomposite test articles were fabricated by high shear mixing, casting, curing, and post-curing in an open face mold under a nitrogen environment. Short-term creep/creep recovery experiments were conducted at prescribed combinations of temperatures (23.8 – 69.2 C), applied stresses (30.2 – 49.8 MPa), and VGCNF weight fractions (0.00 – 1.00 parts of VGCNF per hundred parts of resin, phr) determined from the CCD. The response surface models (RSMs) for predicting these viscoelastic responses were developed using the least squares method and an analysis of variance procedure. The response surface estimates indicate that increasing the VGCNF weight fraction decreases the creep resistance of the VGCNF/VE nanocomposites at high temperatures (46.5 – 69.2 C). Creep Compliance VGCNF Viscoelasticity Creep Nanocomposites Polymers Design of Experiments Creep Rate Central Composite Design Vapor-grown Carbon Nanofibers Vinyl Ester
854	[en] PROPERTIES OF A POLYMERIC ANTICORROSIVE COATING WITH GRAPHENE AS NANOFILLER / [pt] PROPRIEDADES DE REVESTIMENTO ANTICORROSIVO POLIMÉRICO NANOADITIVADO COM GRAFENO MARIO NOGUEIRA BARBOSA JUNIOR 31 August 2020 (has links) [pt] Revestimentos funcionais ou inteligentes (orgânicos, inorgânicos ou híbridos) são materiais que podem ser adaptados para muitas aplicações em que devem ser capazes de executar um conjunto bem definido de funções, como propriedades químicas, mecânicas, elétricas e magnéticas melhoradas. Um dos objetivos deste projeto foi estudar a eficiência do grafeno nanoaditivado em um revestimento epóxi anticorrosivo. Os compósitos foram sintetizados pela adição de grafeno nos teores de 0,1 e 0,5 porcento (p / p) a um revestimento de dois componentes. Para a caracterização do grafeno, foram obtidos difratogramas de DRX e imagens de AFM. Técnicas de caracterização como espectroscopia no infravermelho por transformada de Fourier (FTIR) e Raman foram aplicadas para obtenção de informações relevantes da estrutura molecular e modo de interação entre moléculas da resina epóxi e do grafeno. A análise térmica foi realizada para avaliar a resistência térmica do material e determinar a temperatura de transição vítrea do nanocompósito curado. Os resultados dos testes de termogravimetria não indicaram uma alteração significativa na Tg (transição vítrea da matriz polimérica) com a adição da nanocarga. Isso pode estar relacionado à uma cura incompleta da resina e/ou defeitos grafíticos presentes na amostra de grafeno utilizada. Os testes de imersão em célula atlas e ensaios cíclicos mostraram que as adições de grafeno promovem melhorias no revestimento epóxi no que diz respeito à resistência à corrosão, especialmente na concentração de 0,1 porcento em peso. Devido à demanda significativa da indústria por proteção contra corrosão do aço, o entendimento da interação entre o revestimento epóxi e o grafeno como carga é muito relevante no sentido de encontrar propriedades anticorrosivas superiores. / [en] Functional or smart coatings (organic, inorganic, or hybrid) are materials that can be adapted for many applications where they must be able to perform a well-defined set of functions such as improved theirs chemical, mechanical, electrical and magnetic properties. One of the objectives of this project was to study the efficiency of nanoaditivated graphene in an anticorrosive epoxy coating. The composites were synthesized by the addition of graphene in a polymeric matrix in the contents of 0.1 and 0.5 percent (w/w). For the graphene characterization, XRD diffractograms and AFM images were obtained. Characterization techniques such as Fourier Transform Infrared Spectroscopy (FTIR) and Raman were applied to obtain relevant information on the molecular structure and interaction between epoxy resin and graphene molecules. Thermal Analysis was performed to analyze the material thermal resistance and to determine the glass transition temperature of cured nanocomposite. The thermogravimetry results did not indicate a significant change in the glass transition temperature of the polymeric matrix when submitted to the addition of the nanocharge. This may be related to an incomplete curing process of the resin and/or the presence of defects in the graphene sample. Atlas cell immersion tests and cyclic tests results indicate that graphene additions promote improvements to the epoxy coating concerning corrosion resistance, especially at the concentration of 0.1 percent by weight. Because of the significant demand of industry for steel corrosion protection, the understanding of interaction between epoxy coating and graphene as a filler is very relevant in direction to find out superior anticorrosive properties. [pt] CORROSAO [pt] RESINA EPOXI [pt] GRAFENO [pt] NANOCOMPOSITOS [pt] REVESTIMENTO [en] CORROSION [en] EPOXY RESIN [en] GRAPHENE [en] NANOCOMPOSITES [en] COATING
855	Flexible and recyclable electronics made from nanoreinforced silk / Flexibla och återvinningsbara elektronikkomponenter baserade på nanoförstärkt spindelsilke Bukovský, Marek January 2020 (has links) Forskningsområdet för bärbar elektronik är fortfarande relativt ungt och det finns ett stort behov av utveckling av nya material inom området. Olika typer av kompositer är mycket intressanta och de ska uppvisa såväl hög hållfasthet som goda ledande egenskaper. I detta avseende är silkes fibroin och MXene mycket intressanta utgångsmaterial eftersom silkestrådarna kan ge en struktur med god jonledningsförmåga och god flexibilitet och MXene kan bidra med hög styvhet och god elektrisk ledningsförmåga. Med detta som bakgrund beslöts att undersöka om kompositer av silkestrådar och MXene kan användas i kompositer som kan användas i bärbar elektronik. 3 olika typer av hydrogeler studerades och de innehöll silkes fibroin med 0, 1 och 5% MXene. De egenskaper som utvärderades var struktur, mekaniska egenskaper, stabilitet i vatten, bionedbrytbarhet och både statisk och dynamisk ledningsförmåga. Resultaten visar att de tillverkade nanokompositerna har lovande förutsättningar inom området eftersom en kombination av silkes fibroin med 5 % MXene har god stabilitet, konduktivitet och en hög och stabil Gauge-faktor. / As the research area of wearable electronics is still relatively new, material science with this focus opens plenty of unexplored fields. That is why a study characterizing the unexplored composite system of silk fibroin and MXene (Silk/MXene) was conducted. These two biocompatible materials are complementary with regard to the requirements for wearable electronics materials. Silk fibroin dispose an ionic conductivity and solid flexibility, while MXene brings mechanical strength and significant increase of electrical conductivity. The reinforced hydrogel materials were studied at two concentrations of fillers, 1% and 5% and compared to pristine silk fibroin. All three materials were studied from the point of view of their structure, mechanical properties, behaviour in aqueous environment, biodegradability and electrical conductivity, both static and dynamic. Nanocomposite systems of silk fibroin and MXene have shown a potential for being used in the intended application area, as Silk/MXene 5% film displays good stability, conductivity with high andstable Gauge factor. Wearable electronics flexible electronics silk fibroin MXene nanocomposites Bärbar elektronik flexibel elektronik silkes fibriller MXene nanokompositer Materials Chemistry Materialkemi
856	Reinforcement of Natural Rubber by “Expanded Clay” Adopting “Propping-Open Approach” Rooj, Sandip 04 November 2013 (has links) During the last years rubber nanocomposites obtained by incorporating anisotropic clay nanoparticles within a rubber matrix to tailor material properties have attracted steadily growing interest. However, one main complication preventing rubber-clay nanocomposites from many potential applications is the difficulty to achieve a high degree of exfoliation particularly in case of melt mixing or compounding (using mixing equipment like internal mixer, two roll mills which can be up-scaled in industry). Albeit commercially available organomodified montmorillonite clays (OMt) are fairly compatible with the polar rubber like Acrylo-nitrile butadiene rubber (NBR), carboxylated nitrile rubber (XNBR), chloroprene rubber (CR) etc., its dispersion in non-polar rubbers like natural rubber (NR), is rather unsatisfactory. Incorporation of only 5 phr of OMt in NR by mechanical mixing leads to very poor dispersions with larger aggregates. Large agglomerates of OMt were observed with bare eyes throughout the matrix. Even in the TEM micrographs, highly agglomerated structures of clay particle were observed. A high degree of exfoliation of such clay is achieved in NR utilizing the so called ‘Propping-open approach’ where stepwise expansion of interlayer spacing of Mt took place. A series of long chain fatty acids (C16-C22) are intercalated into the interlayer space of OMt and a gradual expansion of the interlayer space were observed as the chain length of the fatty acid increased. Wide angle X-ray diffraction (WAXD), Fourier transform infrared spectroscopy (FTIR) and contact angle measurement indicated successful intercalation of the fatty acids into the interlayer space of the clay minerals. Since the fatty acid containing 22 carbon atoms has the largest interlayer distance among the modified samples studied, it has been selected for further study to understand the reinforcing behavior in NR matrix. An unusual mechanical percolation behavior of EOMt nanoparticles was observed in a NR matrix. The value of the mechanical percolation threshold (φp) and the fractal nature of nanoparticle clusters were determined through an analysis of the experimental data based on a theory put forward by Huber and Vilgis. This phenomenon was discussed in terms of fractal dimensions of the nanoparticle cluster. The impact of filler dispersion and rubber-filler interactions on the viscoelastic behavior of NR nanocomposites was systematically investigated. Significant non-linear viscoelastic behavior (Payne effect) was observed at very low EOMt content. Kraus and Maier-Göritz models were utilized to interpret such non-linear viscoelastic behavior. The nanocomposites showed enormous improvement in different physic-mechanical properties in the presence of EOMt. Technical elastomers are generally filled with certain fillers (e.g. carbon black) in order to reinforce the rubber matrix for some typical applications like tires, conveyer belts etc. Such rubber goods are always exposed to cyclic stress and deformations attributed to their dynamic application. Under constant and repeated applied stress, cracks develop at a stress concentration point, which could lead to ultimate failure. Therefore, the crack initiation and propagation behavior in such rubber products is very fundamental and need proper attention. The role of EOMt nanoparticles on the microstructure and fracture mechanical behavior of CB filled NR composites was investigated. Using pure-shear test specimen tear fatigue analysis (TFA) tests under cyclic conditions were carried out to explicate the crack growth behavior of CB filled NR in the presence of EOMt. A significant reduction in crack growth rate was noticed in the presence of only 5 phr of EOMt. Furthermore, instrumented tensile-impact tests (IT-IT) were also performed for the characterization of the crack resistance of the materials under impact-like loading conditions. / Die Einarbeitung von nur 5 phr organisch modifizierten Montmorillonite (OMt) in Naturkautschuk (NR) durch mechanisches Mischen führt zu einer sehr schlechten Verteilung mit größeren Aggregaten. Große Agglomerate von OMt waren mit bloßem Auge in der NR Matrix sichtbar. Sogar in TEM Aufnahmen wurden stark agglomerierte Strukturen beobachtet. Ein hoher Grad der Exfolierung von diesem Clay in NR wird durch die Nutzung des so genannten ‘Propping-open’ Ansatzes erreicht, in dem eine stufenweise Aufweitung des Zwischenschichtabstandes des OMt stattfindet. Eine Reihe langkettiger Fettsäuren (C16 – C22) wurde in die Zwischenschicht des OMt eingefügt. Mit zunehmender Kettenlänge der Fettsäuren wurde eine allmähliche Aufweitung der Zwischenschicht beobachtet. Da OMt, der mit einer Fettsäure mit 22 Kohlenstoffatomen modifiziert wurde, den größten Zwischenschichtabstand aller untersuchten Proben hatte, wurde diese Fettsäure für die weiteren Untersuchungen ausgewählt, um das Verstärkungsverhalten in der NR Matrix zu verstehen. Ein ungewöhliches Perkolationsverhalten der expandierten OMt (EOMt) Nanopartikel wurde in einer NR Matrix beobachtet. Der Wert der mechanischen Perkolationsschwelle (φp) und die fraktale Natur der Nanopartikel Cluster wurden durch eine Analyse der experimentellen Daten bestimmt, wobei eine Theorie, die von Huber und Vilgis vorangetrieben wurde, zur Anwendung kam. Dieses Phänomen wurde in Bezug auf die fraktalen Dimensionen der Nanopartikel Cluster diskutiert. Die Einfluss von EOMt Nanopartikel auf die Mikrostruktur und das mechanische Bruchverhalten von russgefüllten NR Kompositen wurde untersucht. Unter Verwendung reiner Schertestproben wurden Rissermüdungsanalysen unter zyklischer Belastung ausgeführt, um das Risswachstumsverhalten von russgefülltem NR in der Gegenwart von EOMt zu untersuchen und zu erklären. Eine signifikante Reduktion der Rissausbreitungsrate wurde in Gegenwart von nur 5 phr EOMt erreicht. Des Weiteren wurden auch instrumentierte Schlagzugprüfungen zur Charakterisierung des Risswiderstandes von Materialien unter schlagartigen Belastungsbedingungen durchgeführt. info:eu-repo/classification/ddc/620 ddc:620
857	Application of High-Deflection Strain Gauges to Characterize Spinal-Motion Phenotypes Among Patients with CLBP Baker, Spencer Alan 12 April 2024 (has links) (PDF) Chronic low back pain (CLBP) is a nonspecific and persistent ailment that entails many physiological, psychological, social, and economic consequences for individuals and societies. Although there is a plethora of treatments available to treat CLBP, each treatment has varying efficacy for different patients, and it is currently unknown how to best link patients to their ideal treatment. However, it is known that biopsychosocial influences associated with CLBP affect the way that we move. It has been hypothesized that identifying phenotypes of spinal motion could facilitate an objective and repeatable method of determining the optimal treatment for each patient. The objective of this research was to develop an array of high deflection strain gauges to monitor spinal motion, and use that information to identify spinal-motion phenotypes. The high deflection strain gauges used in this endeavor exhibit highly nonlinear electrical signal due to their viscoelastic material properties. Two sub-models were developed to account for these nonlinearities: the first characterizes the relationship between quasistatic strain and resistance, and the second accounts for transient electrical phenomena due to the viscoelastic response to dynamic loads. These sub-models are superimposed to predict and interpret the electrical signal under a wide range of applications. The combined model accurately predicts sensor strain with a mean absolute error (MAE) of 1.4% strain and strain rate with an MAE of 0.036 mm/s. Additionally, a multilayered architecture was developed for the strain gauges to provide mechanical support during high strain, cyclic loads. The architecture significantly mitigates sensor creep and viscoplastic deformation, thereby reducing electrical signal drift by 74%. This research also evaluates the effects of CLBP on patient-reported outcomes. An exploratory factor analysis revealed that there are five primary components of well-being: Pain and Physical Limitations, Psychological Distress, Physical Activity, Sleep Deprivation, and Pain Catastrophizing. The presence of CLBP has adverse effects on all these components. It was also observed that different patient reported outcomes are highly correlated with each other, and the presence of CLBP is a significant moderating factor in many of these relationships. Arrays of high-deflection strain gauges were used to collect spinal kinematic data from 274 subjects. Seven phenotypes of spinal motion were identified among study participants. Statistical analyses revealed significant differences in the patient-reported outcomes of subjects who exhibited different phenotypes. This is a promising indication that the phenotypes may also provide important information to clinicians who treat patients suffering from CLBP. Future research will be conducted to develop and identify the optimal treatments for patients according to their phenotypes, which has the potential to reduce medical costs, expedite recovery, and improve the lives of millions of patients worldwide. nanocomposites high-deflection strain gauges modeling patient-reported outcomes phenotyping machine learning chronic low back pain Engineering
858	Suivi de l'état de dispersion des nanoparticules d'argile dans un polymère par rhéo-spectroscopie Attayebi, Houda 18 April 2018 (has links) L'étude expérimentale développée dans ce travail s'articule autour de deux phases principales. La première est la conception d'un système nanocomposite dont les éléments constituants ont été choisis judicieusement en vue d'améliorer ses performances. Le système proposé appartient à la famille des matériaux nanocomposites. Ce système est constitué d'une matrice polymère renforcée par des éléments argileux. Une étude expérimentale a été menée afin d'optimiser le choix de la matrice polymère. En effet, il a été trouvé démontré que lorsque le PDMS est greffé par des radicaux époxydes, sa compatibilité avec la Cloisite C30B devient nettement meilleure. Au niveau de cette même phase, une autre étude expérimentale a été entreprise afin de suivre l'évolution de la structure du mélange en fonction du taux de renfort. En effet, un taux de 2% de la C30B a été jugé approprié pour améliorer les performances du système étudié. Cette première phase du projet a donc abouti à la conception d'un système nanocomposite dit PDMS-Epoxyde/2%C30B. La deuxième phase du présent travail porte sur l'évaluation de l'effet des différents facteurs de cisaillement sur les phénomènes de dispersion-distribution des nanoparticules de Cloisite C30B au sein su polydiméthylsiloxane-epoxyde. Trois facteurs ont été retenus pour cette étude. Le premier étant l'effet du taux de cisaillement "la contrainte de cisaillement" sur l'efficacité du processus d'exfoliation des nanoparticules d'argile dans la matrice polymère. Selon les résultats obtenus, un taux de cisaillement adéquat favorise F intercalation et l'exfoliation mais à un degré assez limité. Cependant, sous l'effet de la déformation, il a été démontré que la qualité de la dispersion /distribution des lamelles d'argile dans la matrice polymère est meilleure que celle obtenue dans le premier cas. Le dernier élément de l'étude expérimentale développée dans le cadre de cette thèse stipule que l'effet de la diffusion moléculaire des chaînes du polymère sur la dispersion-distribution des lamelles d'argile d'une façon individuelle au sein du volume matriciel, sans apport du cisaillement, permet également d'atteindre un niveau avancé d'exfoliation-percolation. TP 7.5 UL 2011 A883 Matériaux nanocomposites Composites polymères Minéraux argileux Argile Cisaillement (Mécanique) Percolation Rhéologie Rayons X -- Diffraction
859	Synthesis and characterization of metal oxide thin films, metal sulfide and metal oxide polymer nanocomposites and studies of their application in water treatment Xaba, Thokozani 10 August 2017 (has links) Ph. D. (Department of Chemistry, Faculty of Applied and Computer Sciences), Vaal University of Technology. / The study based on thiourea derivatives has received significant interest from several disciplines due to their variable bonding modes, promising biological implications and their complexation capacity. Thiosemicarbazones are a stimulating type of ligands that reveals a diverse range of biological activities. They are effectual intermediates for the production of pharmaceutical and bioactive materials which makes them very useful in the field of medicinal chemistry. The FTIR spectral variations in the stretching frequencies of C=N, C–N and C=S that appeared at 1663, 1327 and 726 cm-1, respectively confirmed the formation of the ligand. The present study describes the preparation of (Z)-2-(pyrrolidin-2-ylidene)thiourea ligand for the synthesis of ZnS, CdS and Ag2S nanoparticles via homogeneous/chemical precipitation technique. The effect of different capping agents such as starch, PVP, PEG, PVA, and the role of ammonium hydroxide solution during the synthetic processes was investigated and distinguished. The study based on the effect of capping molecule on the formation of nanoparticles proved that the capping agent has a great influence on the formation of nanoparticles. The FTIR spectra of the capped nanoparticles revealed the shift toward the higher frequencies compared with the uncapped metal sulfide nanoparticles. The metal sulfide nanoparticles also showed an increased in energy band gaps which were different from the bulk materials. The 2-hydroxy-1-naphthaldehyde is regarded as a low-cost ligand which has also been widely used in biological synthesis to determine free amino acid groups. The metal complexes of this ligand are easily prepared and can be used to synthesize metal oxide nanomaterials at low cost which are environmentally friendly that can be expended in bio-applications. The preparation of the Zn, Cd and Ag complexes based on the bis(2- hydroxy-1-naphthaldehydate ligand through the reaction desired metal acetate are reported and confirmed by FTIR spectroscopy, elemental analysis and thermogravimetric analysis (TGA). There has been a great research significance for the synthesis of metal oxide since such materials have high specific surface area and a high fraction of surface atoms. The synthesis of ZnO, CdO and Ag2O nanoparticles through thermal decomposition of the Zn(II), Cd(II) and Ag(I) complexes into trioctylphosphene oxide (TOPO) and/or hexadecylamine (HDA) at different decomposition temperatures is reported. The study proved that the combination of oleylamine as a solvent and TOPO as a capping molecule produced controlled shaped and reasonably dispersed particles. The XRD patterns of all the metal oxide nanoparticles synthesized with TOPO were showing face-centred cubic structures. These metal oxide based complexes were also used as single source precursors to prepare metal oxide thin films at different annealing temperatures on the glass substrate using different methods such as annealing, thermal decomposition, aerosol assisted chemical vapour deposition (AACVD) methods. The optical absorption and size distribution of the synthesized nanoparticles and thin films have been explored using XRD, SEM, AFM, FTIR, PL and UV-Vis spectroscopy techniques. The results show that the decomposition temperature has a huge effect on the formation of the nanomaterials. The SEM images of the as synthesized nanoparticles revealed different shapes of the particles as the decomposition temperature is increased. A change in X-ray diffraction parttern was observed when the decomposition temperatures were increased. The capped metal sulphides and metal oxide nanoparticles were then allowed to react with polydadmac or chitosan to form the polymer nanocomposites. The optical absorption, luminescence properties, size distribution and the bonds distribution of the polymer nanocomposites were characterized with UV-Vis, PL and FTIR spectroscopy. The structural and morphological properties have been studied by XRD, TEM and SEM. The absorption analysis of the prepared nanocomposites revealed the properties of both nanoparticles and polymers. Chitosan and polydadmac are biopolymers that have been proven as the best adsorbents to remove the heavy metal ions from wastewater.In this study, polydadmac and chitosan based metal sulphide and metal oxide nanocopmposites were used as adsorbents for the removal of Fe(III) from the wastewater. The batch experiments were conducted to achieve the optimum conditions. The effect of pH, contact time, and initial metal ion concentration were also determined. The pH = 8 was found to be the optimum pH for the removal of Fe(II) ions from the water sample by utilizing pure chitosan and chitosan nanocomposites as adsorbents. Metal oxide polymer Nanocomposites Water treatment Metal sulfide nanoparticles Dissertations, Academic -- South Africa Nanostructured materials Water -- Purification Polymers.
860	COLLOIDAL INTERACTIONS AND STABILITY IN PROCESSING, FORMATION AND PROPERTIES OF INORGANIC-ORGANIC NANOCOMPOSITES Alhassan, Saeed M. 04 May 2011 (has links) No description available. Chemical Engineering clay graphene graphene oxide aerogel laponite turbulence exfoliation colloidal interactions DLVO theory colloidal stability nanocomposites

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