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Influence of Molecular Orientation and Surface Coverage of w-Functionalized Mercaptans on Surface AcidityTaylor, Charles Douglas 02 December 2000 (has links)
The compounds 12-phenoxy-dodecane-1-thiol, 4-dodecyloxymercaptophenol and 3-dodecyloxymercaptophenol have been synthesized using a novel synthesis to investigate the effect that the orientation of the functional group has on surface acidity. 3-dodeycloxymercaptophenol and 4-dodecyloxymercaptophenol differ in that the hydroxyl group is substituted on different carbons of the benzene ring. The difference in substitution patterns should present the hydroxyl group in different orientations in the interface between a self-assembled monolayer of the compound and aqueous solutions buffered over a pH range of 3-13. By preparing self-assembled monolayers of these molecules on gold substrates, the ability of the hydroxyl group to donate its proton was shown to depend on the hydroxyl group substitution pattern on the benzene ring through contact angle titration experiments. 3-dodecyloxymercaptophenol clearly showed plateaus at low and high pH with a broad transition between the two plateaus. 4-dodecyloxymercaptophenol showed a clear plateau at low pH but not at high pH, although a transition was observed. Using infrared spectroscopy, it was further shown that the long molecular axis of the benzene ring in 3-dodecyloxymercaptophenol was tilted from the surface normal by 55°. The short molecular axis of the ring was twisted out of the plane of the surface by 28° for self-assembled monolayers of this molecule on gold substrates. In contrast, the tilt angle of 4-dodecyloxymercatophenol was measured to be 46° and was twisted out of the surface plane by 36°. It was also found from cyclic voltammetry experiments in 0.5 M KOH, that the ionized monolayers of 4-dodecyloxymercaptophenol were 2.3 kJ/mol less stable than monolayers of 3-dodecyloxymercaptophenols. This finding suggests that hydrogen bonding and other intermolecular interactions in 4-dodecyloxymercaptophenol are greater than in 3-dodecyloxymercaptophenol. / Ph. D.
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Water and salt transport structure/property relationships in polymer membranes for desalination and power generation applicationsGeise, Geoffrey Matthew 22 September 2014 (has links)
Providing sustainable supplies of water and energy is a critical global challenge. Polymer membranes dominate desalination and could be crucial to power generation applications, which include reverse osmosis (RO), nanofiltration (NF), forward osmosis (FO), pressure-retarded osmosis (PRO), electrodialysis (ED), membrane capacitive deionization (CDI), and reverse electrodialysis (RED). Improved membranes with tailored water and salt transport properties are required to extend and optimize these technologies. Water and salt transport structure/property relationships provide the fundamental framework for optimizing polymer materials for membrane applications. The water and salt transport and free volume properties of a series of sulfonated styrenic pentablock copolymers were characterized. The polymers' water uptake and water permeability increase with degree of sulfonation, and the block molecular weights could be used to tune water uptake, permeability, and selectivity properties. The presence of fixed charge groups, i.e., sulfonate groups, on the polymer backbone influence the material's salt transport properties. Specifically, the salt permeability increases strongly with increasing salt concentration, and this increase is a result of increases in both salt sorption and diffusivity with salt concentration. The data for the sulfonated polymers, including a sulfonated polysulfone random copolymer, are compared to those for an uncharged polymer to determine the influence of polymer charge on salt transport properties. The sulfonated styrenic pentablock copolymer permeability data are compared to literature data using the water permeability and water/salt selectivity tradeoff relationship. Fundamental transport property comparisons can be made using this relationship. The effect of osmotic de-swelling on the polymers and the transport properties of composite membranes made from sulfonated styrenic pentablock copolymers are also discussed. The sulfonated styrenic pentablock copolymers were exposed to multi-valent ions to determine their effect on the polymer's salt transport properties. Magnesium chloride permeability depends less on upstream salt concentration than sodium chloride permeability, presumably due to stronger association between the sulfonate groups and magnesium compared to sodium ions. Triethylaluminum was used to neutralize the polymer's sulfonic acid functionality and presumably cross-link the polymer. The mechanical, transport, and free volume properties of these aluminum neutralized polymers were studied. / text
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Efeito das condições de processamento e da adição de borracha trans-polioctenileno nas propriedades de blendas de borracha natural/estireno butadieno. / Effect of processing ponditions and addition of trans-polyoctenylene rubber on the properties of natural rubber/styrene butadiene rubber blends.Bizi, Claudia Maria Pena 04 October 2007 (has links)
Blendas poliméricas são largamente utilizadas nas indústrias de pneus por causa de seu baixo custo e das melhores propriedades que podem ser obtidas. Quando os componentes da blenda não são miscíveis entre si, métodos de compatibilização química (utilizando agentes compatibilizantes) ou mecânica (aumentando o tempo de mistura dos elastômeros) são necessários para melhorar a compatibilidade dos componentes da mistura. Neste trabalho, o Trans-Polioctenileno (TOR) foi usado como agente compatibilizante da blenda de NR/SBR. A viscosidade Mooney, a Carga e o Alongamento na Ruptura de diversas blendas foram avaliados, utilizando um planejamento fatorial. Os resultados obtidos mostraram que o TOR tem maior influência na alteração da viscosidade Mooney, seguido pelo tempo de premix e de repasse. No caso das propriedades dinamométricas, a carga e o alongamento na ruptura são mais sensíveis às alterações do tempo de processamento dos polímeros. O TOR leva a uma ligeira diminuição destas propriedades. Baseado nos resultados estatísticos, equações de regressão para avaliar as propriedades estudadas em função da concentração de TOR e do tempo de processamento foram propostos e posteriormente verificados, utilizando blendas que não estavam incluídas no planejamento original. Os resultados foram bastante satisfatórios, tanto na determinação dos efeitos das variáveis quanto na determinação das equações. Concluiu-se que a viscosidade Mooney é mais sensível às alterações da concentração de TOR do que às alterações do tempo de mistura dos elastômeros e que as propriedades dinamométricas são mais afetadas pelo tempo de processamento. / Polymer blends are used in tyre industries because of their low cost and better properties. When the blend components are not miscible, chemical methods (using compatibilizing agents) or mechanical methods (increasing the mixture time of elastomers) of compatibilization are necessary to improve the compatibility of the components of the blend. In this work, Trans-Polyoctenylene Rubber (TOR) was used as a compatibilizing agent of the NR/SBR rubber blend. The Mooney viscosity, stress and elongation at break of different blends were evaluated, using a Factorial Design. The experimental results obtained showed that the Mooney viscosity is greatly affected by the addition of TOR whereas the dynamometric properties, the stress and elongation at break are more sensitive to the changes of processing time of polymers. Based on statistical results, regression equations to evaluate the properties studied as a function of TOR concentration and processing time were obtained and verified using blends which were not on the original design. The results were very satisfactory, either on the effects determination or on the regression equation determination. It was concluded that the Mooney viscosity is more sensitive to the alterations of TOR concentration than the changes in the processing time of the elastomers and the dynamometric properties are more affected by the processing time.
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CARBON QUANTUM DOTS: BRIDGING THE GAP BETWEEN CHEMICAL STRUCTURE AND MATERIAL PROPERTIESPillar-Little, Timothy J., Jr. 01 January 2018 (has links)
Carbon quantum dots (CQDs) are the latest generation of carbon nanomaterials in applications where fullerenes, carbon nanotubes, and graphene are abundantly used. With several attractive properties such as tunable optical property, edge-functionalization, and defect-rich chemical structure, CQDs have the potential to revolutionize optoelectronics, electro- and photocatalysis, and biomedical applications. Chemical modifications through the addition of heteroatoms, chemical reduction, and surface passivation are found to alter the band gap, spectral position, and emission pathways of CQDs. Despite extensive studies, fundamental understanding of structure-property relationship remains unclear due to the inhomogeneity in chemical structure and a complex emission mechanism for CQDs.
This dissertation outlines a series of works that investigate the structure-property relationship of CQDs and its impact in a variety of applications. First, this relationship was explored by modifying specific chemical functionalities of CQDs and relating them to differences observed in optical, catalytic, and pharmacological performance. While a number of scientific articles reported that top-down or bottom-up synthesized CQDs yielded similar properties, the results herein present dissimilar chemical structures as well as photoluminescent and metal sensing properties. Second, the role of nitrogen heteroatoms in top-down synthesized CQD was studied. The effect of nitrogen atoms on spectral position and fluorescence quantum yield was considerably studied in past reports; however, thorough investigation to differentiate various nitrogen related chemical states was rarely reported. By finely tuning both the quantity of nitrogen doping and the distribution of nitrogen-related chemical states, we found that primary amine and pyridine induce a red-shift in emission while pyrrolic and graphitic nitrogen produced a blue-shift in emission. The investigation of nitrogen chemical states was extended to bottom-up synthesized CQDs with similar results. Finally, top-down, bottom-up, nitrogen-doped and chemically reduced CQDs were separately tested for their ability to act as photodynamic anti-cancer agents. This series of experiments uncovered the distribution of reactive oxygen species produced during light exposure which elucidated the photodynamic mechanisms of cancer cytotoxicity. The results presented in this dissertation provide key insight into engineering finely-tailored CQDs as the ideal nanomaterial for a broad range of applications.
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Structure-property relationship in core-shell rubber toughened epoxy nanocompositesGam, Ki Tak 30 September 2004 (has links)
The structure-property relationships of epoxy nanocomposites with inorganic layer-structure nanofillers have been studied to obtain the fundamental understanding of the role of nanofillers and the physics of polymer nanocomposites in this dissertation. Several polymer nanocomposite systems with modified montmorillonite (MMT) or α-zirconium phosphate (ZrP) nanofillers were prepared with epoxy matrices of different ductility and properties. The successful nanofiller's exfoliations were confirmed with X-ray diffraction and transmision electronic microscopy (TEM). Dynamic mechanical analysis (DMA) on the prepared epoxy nanocomposites revealed the significant increase in rubbery plateau moduli of the epoxy nanocomposite systems above Tg, as high as 4.5 times, and tensile test results showed improved modulus by the nanofiller addition, while the fracture toughenss was not affected or slightly decreased by nanofillers. The brittle epoxy nanocomposite systems were toughened with core shell rubber (CSR) particles and showed remarkable increase in fracture toughness (KIC) value up to 270%. The CSR toughening is more effective at ductile matrices, and TEM observation indicates that major toughening mechanisms induced by the CSR addition involve a large scale CSR cavitation, followed by massive shear deformation of the matrix.
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Approaches to Tailoring the Structure and Properties of PolyethyleneLi Pi Shan, Colin January 2002 (has links)
Alternative methods to control the molecular weight and short chain branching distribution of polyethylene were investigated. The ability to produce polyolefins with multimodal microstructural distributions using single catalyst/single reactor set-up is very attractive and could, in principle, be used to produce polyolefin resins with advanced molecular architecture. In this thesis, resins with controlled microstructures were produced, characterized and properties tested in order to develop a better understanding of polymerization structure-property relationships. Copolymerizations of ethylene and 1-hexene were carried out with an in-situ supported metallocene catalyst. Copolymers were produced with different alkylaluminum activators and the effect on molecular weight and short chain branching distributions was examined. It was found that different activator types produce polymer with unimodal and narrow molecular weight distributions but with very different short chain branching distributions. Each activator exhibits unique comonomer incorporation characteristics to produce bimodal short chain branching distributions with the use of a single activator. By using individual and mixed activator systems, it is possible to control the short chain branching distributions of the resulting copolymers while maintaining narrow molecular weight distributions. To further investigate the capabilities of this in-situ supported catalyst system, an experimental design was carried out to study the effect of polymerization conditions on the catalyst activity and microstructure of poly(ethylene-co-1-octene). The parameters investigated were: polymerization temperature, monomer pressure, chain transfer to hydrogen, comonomer/ethylene feed ratio and concentration of alkylaluminum. The effect of each parameter on the catalyst activity, comonomer incorporation and molecular weight distribution was investigated. The results obtained were not typical of a conventional single-site catalyst. The copolymerization system was sensitive to all of the parameters and many interactions were evident. The most prominent effect was the catalyst response to temperature. As the temperature was decreased, the short chain branching distributions of the copolymers became broad and bimodal. Overall, it was found that a wide range of microstructures could be produced, ranging from copolymers with low and high 1-octene content with unimodal to broad short chain branching distributions, and from low to high molecular weight with narrow to broad molecular weight distributions. To examine the effect of these broad short chain branching distributions on the polymer properties, a series of poly(ethylene-co-1-hexene) resins with very distinct, and in some cases bimodal crystalline distributions, were synthesized. The attractive feature of the resins in this study is that their molecular weight distributions are similar but each possesses a different short chain branching distribution, thus effectively minimizing the effect of molecular weight on the properties investigated. It was found that the tensile properties of a copolymer could be controlled by the ratio of the crystalline species present in the sample. In this study, a balance of stiffness and toughness was exhibited by a copolymer containing a large proportion of crystalline material and a small fraction of material of lower crystallinity. A series of poly(ethylene-co-1-octene) resins with tailored molecular weight and short chain branching distributions were synthesized with a heterogeneous metallocene catalyst in a two-stage polymerization process. Blends of high molecular weight copolymer and low molecular weight homopolymer and reverse blends of low molecular weight copolymer and high molecular weight homopolymer were produced. The physical properties of these resins were tested for their dynamic mechanical (tensile) and rheological properties. Increasing the copolymer content in the blend resulted in a decrease in stiffness. However, the energy dampening properties of these blends benefit from the presence of the copolymer. It was also confirmed that the melt flow properties of polymers mostly depend on their molecular weight distribution. Regardless of the comonomer content, the melt viscosities decreased with the addition of low molecular weight polymer.
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Structure and Property Correlations in Heavy Atom RadicalsLeitch, Alicea Anne 06 1900 (has links)
Neutral radicals represent versatile building blocks for the design of new conductive and magnetic molecular materials. In order to obtain good electron transport, materials displaying a high bandwidth W and a low on-site Coulomb repulsion energy U must be generated, and to this end, the pyridine-bridged bisdithiazolyl radicals were developed. As a result of resonance stabilization, these materials possessed a low U, a high thermal stability, and did not dimerize in the solid state. Unfortunately, their crystal structures consisted of slipped π-stack arrays that limited overall bandwidth and afforded Mott insulating ground states. To improve on these systems, two strategies were employed to increase orbital overlap between radicals. The first approach involved the removal of one of the R groups to allow for more superimposed π-stacking in the solid state. Although the desired packing motif was achieved for one derivative, and higher conductivity was observed, a subtle distortion along the π-stacks at low temperature resulted in diamagnetic behaviour, demonstrating the need for steric protection in preventing spin-quenching association in these compounds. The second strategy to improve W was to incorporate the heavier, more spatially diffuse selenium atom into the framework. Three selenium-containing isomers were developed and it was found that conductivity increased with selenium content, with room temperature values reaching 0.001 S/cm. For some derivatives σ-dimerization through the selenium atom is observed, and these compounds exhibited a dramatic response to applied pressure, with conductivity values increasing by 5 orders of magnitude under 5 GPa of pressure. When dimerization is avoided, isomorphous mapping of sulfur for selenium is generally achieved, although for one series of radicals, two space groups were obtained. For this family of compounds the effects of the crystal structure on the transport properties were examined. A series of EHT bandwidth calculations and DFT magnetic exchange energy calculations on a model 1D π-stack of radicals revealed that the experimental properties (both conductivity and magnetism) correlate well to theory, suggesting that the behaviour of these compounds can be predicted based on crystal structure, and that the design of compounds with specific properties may soon be possible.
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Approaches to Tailoring the Structure and Properties of PolyethyleneLi Pi Shan, Colin January 2002 (has links)
Alternative methods to control the molecular weight and short chain branching distribution of polyethylene were investigated. The ability to produce polyolefins with multimodal microstructural distributions using single catalyst/single reactor set-up is very attractive and could, in principle, be used to produce polyolefin resins with advanced molecular architecture. In this thesis, resins with controlled microstructures were produced, characterized and properties tested in order to develop a better understanding of polymerization structure-property relationships. Copolymerizations of ethylene and 1-hexene were carried out with an in-situ supported metallocene catalyst. Copolymers were produced with different alkylaluminum activators and the effect on molecular weight and short chain branching distributions was examined. It was found that different activator types produce polymer with unimodal and narrow molecular weight distributions but with very different short chain branching distributions. Each activator exhibits unique comonomer incorporation characteristics to produce bimodal short chain branching distributions with the use of a single activator. By using individual and mixed activator systems, it is possible to control the short chain branching distributions of the resulting copolymers while maintaining narrow molecular weight distributions. To further investigate the capabilities of this in-situ supported catalyst system, an experimental design was carried out to study the effect of polymerization conditions on the catalyst activity and microstructure of poly(ethylene-co-1-octene). The parameters investigated were: polymerization temperature, monomer pressure, chain transfer to hydrogen, comonomer/ethylene feed ratio and concentration of alkylaluminum. The effect of each parameter on the catalyst activity, comonomer incorporation and molecular weight distribution was investigated. The results obtained were not typical of a conventional single-site catalyst. The copolymerization system was sensitive to all of the parameters and many interactions were evident. The most prominent effect was the catalyst response to temperature. As the temperature was decreased, the short chain branching distributions of the copolymers became broad and bimodal. Overall, it was found that a wide range of microstructures could be produced, ranging from copolymers with low and high 1-octene content with unimodal to broad short chain branching distributions, and from low to high molecular weight with narrow to broad molecular weight distributions. To examine the effect of these broad short chain branching distributions on the polymer properties, a series of poly(ethylene-co-1-hexene) resins with very distinct, and in some cases bimodal crystalline distributions, were synthesized. The attractive feature of the resins in this study is that their molecular weight distributions are similar but each possesses a different short chain branching distribution, thus effectively minimizing the effect of molecular weight on the properties investigated. It was found that the tensile properties of a copolymer could be controlled by the ratio of the crystalline species present in the sample. In this study, a balance of stiffness and toughness was exhibited by a copolymer containing a large proportion of crystalline material and a small fraction of material of lower crystallinity. A series of poly(ethylene-co-1-octene) resins with tailored molecular weight and short chain branching distributions were synthesized with a heterogeneous metallocene catalyst in a two-stage polymerization process. Blends of high molecular weight copolymer and low molecular weight homopolymer and reverse blends of low molecular weight copolymer and high molecular weight homopolymer were produced. The physical properties of these resins were tested for their dynamic mechanical (tensile) and rheological properties. Increasing the copolymer content in the blend resulted in a decrease in stiffness. However, the energy dampening properties of these blends benefit from the presence of the copolymer. It was also confirmed that the melt flow properties of polymers mostly depend on their molecular weight distribution. Regardless of the comonomer content, the melt viscosities decreased with the addition of low molecular weight polymer.
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Structure and Property Correlations in Heavy Atom RadicalsLeitch, Alicea Anne 06 1900 (has links)
Neutral radicals represent versatile building blocks for the design of new conductive and magnetic molecular materials. In order to obtain good electron transport, materials displaying a high bandwidth W and a low on-site Coulomb repulsion energy U must be generated, and to this end, the pyridine-bridged bisdithiazolyl radicals were developed. As a result of resonance stabilization, these materials possessed a low U, a high thermal stability, and did not dimerize in the solid state. Unfortunately, their crystal structures consisted of slipped π-stack arrays that limited overall bandwidth and afforded Mott insulating ground states. To improve on these systems, two strategies were employed to increase orbital overlap between radicals. The first approach involved the removal of one of the R groups to allow for more superimposed π-stacking in the solid state. Although the desired packing motif was achieved for one derivative, and higher conductivity was observed, a subtle distortion along the π-stacks at low temperature resulted in diamagnetic behaviour, demonstrating the need for steric protection in preventing spin-quenching association in these compounds. The second strategy to improve W was to incorporate the heavier, more spatially diffuse selenium atom into the framework. Three selenium-containing isomers were developed and it was found that conductivity increased with selenium content, with room temperature values reaching 0.001 S/cm. For some derivatives σ-dimerization through the selenium atom is observed, and these compounds exhibited a dramatic response to applied pressure, with conductivity values increasing by 5 orders of magnitude under 5 GPa of pressure. When dimerization is avoided, isomorphous mapping of sulfur for selenium is generally achieved, although for one series of radicals, two space groups were obtained. For this family of compounds the effects of the crystal structure on the transport properties were examined. A series of EHT bandwidth calculations and DFT magnetic exchange energy calculations on a model 1D π-stack of radicals revealed that the experimental properties (both conductivity and magnetism) correlate well to theory, suggesting that the behaviour of these compounds can be predicted based on crystal structure, and that the design of compounds with specific properties may soon be possible.
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Mechano-Activated Electronic and Molecular StructuresWang, Ke 2009 December 1900 (has links)
For centuries, researchers have been trying to achieve precise control and tailor
materials properties. Several approaches, i.e., thermo-activation, electro-activation, and
photo-activation, have been widely utilized. As an alternate and fundamentally different
approach, mechano-activation is still relatively less-known. In particular, understanding
the roles of mechano-activated electronic and molecular structures is yet to be achieved.
This research contributes the fundamental understanding in mechanisms of
mechano-activation and its effects on materials properties. Experimental investigation
and theoretical analysis were involved in the present research. A methodology was
developed to introduce the mechnao-activation and to study its subsequent effects. There
are three major areas of investigation involved. First, the means to introduce mechanoactivation,
such as energetic particle collision or a bending deformation (tensile force);
Second, in-situ and ex-situ characterization using AFM, FTIR, UV-Vis, and XPS etc.
techniques; Third, theoretical analysis through modified Lennard-Jones potentials in
order to explain the behavior of materials under mechano-activation.
In the present research, experiments on a Diamond-Like Carbon (DLC) film, a
Polyvinylidene Fluoride (PVDF) film, and the Silver-Crown Ether nanochains (Ag-NCs)
were carried out. For DLC, the collision-induced transformation between hybridization
states of carbon was confirmed, which also dominated the friction behavior of the film.
For PVDF, results show that the applied tensile force induced the transformation of [alpha], [beta],
and [upsilon] crystalline phase. In addition, the transformation observed was time and direction
dependent. For Ag-NCs, a new approach based on the mechanism of mechano-activation
was developed for nanochain structure synthesis. Molecular dynamics simulation and
experimental results revealed that the formation of Ag-NCs is a synergetic physicalchemical
procedure. Experimental results from DLC and PVDF were further used to
validate the proposed potential, which brought new insight into the activation process.
The current research achieves a precise control on engineering materials properties. The
force-activated materials have wide applications in many areas, such as functional
coating, sensing, and catalysis.
In this study selected experiments have demonstrated the effects of mechanoactivation
in different material systems (ceramic, polymer, metallic nano structure) and at
different length scales. For the first time, a modified potential was proposed to explain
the observed mechano-activation phenomena from the energy point of view. It was
validated by experimental results of DLC and PVDF. The current research brings new
understanding in mechano-activation and opens potential for its applications in tailoring
materials properties.
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