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Structure-property relationship of nanoplatelet-reinforced polymer nanocompositesBoo, Woong Jae 15 May 2009 (has links)
As a part of a larger effort towards the fundamental understanding of structureproperty
relationship in nanoplatelet-reinforced polymer nanocomposites, a set of model
epoxy systems containing α-Zirconium Phosphate (α-ZrP) have been prepared and
studied in this dissertation. A new surface modification approach, i.e., the porous
pathway approach, for improving intercalation efficiency and exfoliation of layered
nanoplatelets has been proposed and the effectiveness has been demonstrated. In order to
clearly understand the roles of nanofillers and the effects of their geometric factors on
the physical and mechanical properties of nanocomposites, variables such as
nanoplatelet loading level, degree of exfoliation, and aspect ratio have been carefully
controlled in the epoxy matrices. Morphological information of the prepared
nanocomposites was unambiguously confirmed by carrying out X-ray diffraction and
transmission electron microscopy (TEM). Tensile and thermo-mechanical properties of
the model epoxy/α-ZrP nanocomposites have been investigated. Furthermore, fracture
behavior of the model nanocomposites is examined in this study. This work has
enhanced the understanding of the effects of nanoplatelet, i.e., loading level, degree of exfoliation, aspect ratio, and the type of surface modifiers, on the mechanical properties
and fracture behavior of polymer nanocomposites.
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STRUCTURE PORPERTY RELATIONSHIPS OF HIGH PERFORMANCE POLYBENZOXAZINESLiu, Jia 02 September 2014 (has links)
No description available.
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A surfacelet-based method for constructing geometric models of microstructureJeong, Namin 07 January 2016 (has links)
Integration of material composition, microstructure, and mechanical properties with geometry information enables many product development activities, including design, analysis, and manufacturing. To address such needs, models of material composition have been integrated into CAD systems, creating systems called heterogeneous CAD modeling. In order to support the heterogeneous CAD system, extensive process-structure-property relationships have to be captured and integrated into current CAD system. A new method for reverse engineering of materials will be presented such that microstructure models can be constructed and used in the heterogeneous CAD system.
Reverse engineering of material consists of three parts: image analysis, structure-property-process relationship, and repository. In this research, an image processing method, which comprises the Radon transform and the wavelet transform, will be used in order to recognize geometric features from a microstructure image. Recognizing geometric features can be obtained by combinations of three techniques, masking, clustering, and high frequency component on wavelet transform, that are integrated with the Radon transform. Then, recognized geometric features can be used to construct an explicit geometric model of microstructure. The proposed work will provide an explicit mathematical method to recognize and to quantify microstructure features from an image. In addition, explicit geometric models of microstructure can be automatically constructed and utilized to get effective mechanical properties, establishing structure-property relationship of the material. In order to demonstrate this, polymer nano-composite sample and metal alloy sample will be used.
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An Investigation of Solute Solubility in the Propellant HFA-134aHoye, Julie Annalisa January 2007 (has links)
The reformulation of pressurized metered dose inhalers (MDIs) with hydrofluoroalkanes (HFAs) from chlorofluorocarbons (CFCs) has given rise to many solubility challenges. Compounds and excipients previously used in CFCs were observed to have significantly different solubility values in HFA-134a. In this investigation, the solubility values of solid organic solutes were determined in pure HFA-134a and HFA-134a with cosolvent (0 - 20% w/w ethanol). The solubilities of solid solutes in HFA-134a were also compared with those in 2H,3H-decafluoropentane (DFP) in order to assess the suitability of DFP as a liquid model propellant. The experimental set of solutes display diverse physico-chemical properties and yielded solubility values that ranged over four orders of magnitude. The experimental solubilities were compared to calculated values obtained from ideal solubility and regular solution theory models. While the theoretical models did not offer absolute solubility estimations, a clear correlation with the ideal solubility (melting point) was noted. Further consideration utilizing multiple linear regression models afforded correlations based on molecular properties. Regression models, containing melting point and logP (or molar volume) resulted in promising correlations in both pure HFA-134a and HFA-134a/cosolvent systems where the average absolute errors ranged from 0.49 to 0.82 log units, (average factor errors of 3.09 and 6.61, respectively). In general, a linear relationship was observed between log mole fraction solubility in HFA-134a and fraction ethanol. The effect on solubilization ranged from 1.3 to 99.4 times when 20% w/w ethanol was introduced, relative to pure HFA-134a. DFP appears to be a promising liquid model for pure HFA-134a for pre-formulation calculations. A two parameter equation were found to be significant in pure HFA-134a where the average absolute error (AAE) value was 0.61 log units (average factor errors of 4.07).
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Crystallization and Solid-State Transformation of Pseudopolymorphic Forms of Sodium NaproxenKim, Young-soo 19 July 2005 (has links)
Incorporation of water molecules in the crystal structure of an organic compound has strong effects on its physical and chemical properties. Therefore, the study on stability of water-incorporated pharmaceutical compounds and mechanisms of hydration and dehydration is very important for the pharmaceutical industries.
The main goals of the present research project were quantitative description of the crystallization and solid-state transformations of pseudopolymorphs of sodium naproxen in order to provide fundamental information concerning stability of the pseudopolymorphic forms. Furthermore, macroscopic phenomena of size reduction and anisotropic water-removal by dehydration were rationalized by microscopic aspects of crystal lattice structures.
The heats of solution for each pseudopolymorph were estimated by fitting the solubility data with the vant Hoff equation, and their use was extended by the thermodynamic cycle developed in the present study. According to the thermodynamic cycle, for an enantiotropic system, a form with a lower degree of hydration always has the lower heat of solution than a form with a higher degree of hydration, implying that a form with a lower degree of hydration is more stable.
The relative stabilities of the dihydrated, the monohydrated, and the anhydrous sodium naproxen at 0% relative humidity were investigated by dehydration of the dihydrated form and powder X-ray diffraction. The monohydrate is more stable than the dihydrate and the result was supported by isothermal TGA experiments.
This research explained why powder-like crystals of the anhydrous sodium naproxen were produced by dehydration of hydrated forms. The surfaces of the dehydrated crystals displayed cracks aligned along the b-axis of the monohydrate. These cracks made the anhydrous crystals, which were produced from the monohydrated species, very brittle and, eventually, such crystals were disrupted into much smaller entities. In addition, the existence of water channels in the unit cells of the monohydrate facilitates the dehydration in a direction more rapidly, especially, along the b-axis of the monohydrate. Rapid removal of water in a specific direction caused anisotropic dehydration.
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Colloidal Manipulation of Nanostructures: Stable Dispersion and Self-assemblySun, Dazhi 16 December 2013 (has links)
This dissertation work addresses two important aspects of nanotechnology -
stable dispersion and self-assembly of colloidal nanostructures. Three distinctly
different types of nano-scaled materials have been studied: 0-dimensional ZnO quantum
dots (QDs), 1-dimensional carbon nanotubes (CNTs), and 2-dimensional alpha-zirconium
phosphate (ZrP) nanoplatelets. Specifically, highly crystalline ZrP layered compounds
with differences in diameters have been synthesized and fully exfoliated into monolayer
platelets with uniform thickness, followed by their self-assembly into liquid crystalline
structures, i.e., nematic and smectic. A novel colloidal approach to debundle and
disperse CNTs has been developed by utilizing nanoplatelets to gather and concentrate
sonication energy onto nanotube bundles. In such a fashion, CNTs are fully exfoliated
into individual tubes through physical means to preserve their exceptional physical
properties. Moreover, monodisperse ZnO QDs with high purity have been synthesized
through a simple colloidal approach. Exfoliated ZrP nanoplatelets are used to tune the
dispersion of ligand-free ZnO QDs from micron-sized aggregates to an individual QD level depending on the ratio between nanoplatelets and QDs. Dynamic analysis suggests
that the dispersion mechanism mainly involves the change of QD dispersion free energy
due to the presence of nanoplatelets, so that QDs can interact favorably with the
surrounding media. In addition, the nanoplatelet-assisted dispersion approach has been
utilized to disperse QDs and CNTs into polymeric matrices. Dispersion - property
relationship in polymer nanocomposites has been systematically investigated with
emphasis on optical properties for QDs and mechanical properties for CNTs.
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The Structure-Property Relationship of Cold-Drawn 1010 Steel TubingSullivan, Charles Kenneth 15 August 2014 (has links)
This study focuses on the evolving microstructure and its associated mechanical properties during each step of a seven step manufacturing process for 1010 steel tubing. For the microstructural analysis, we employed optical microscopy to quantify the ferrite grain size and pearlite grain size at each material step. To determine the mechanical properties, we used a Vickers hardness indenter and performed both tension and compression tests at varying strain rates and temperatures. Mechanical tests results indicate decreasing strength with increasing grain size, agreeing with the Hall-Petch relation and were used to correlate hardness and yield strength with grain size. Additionally, tensile and compression tests were performed at different strain rates to examine the effect of microstructural features on the mechanical properties of the steel tubing. Understanding the structure/property relationships of 1010 steel tubing during different processing conditions allows tubing to be manufactured more efficiently with desirable mechanical properties.
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Capturing structure-property relationships of complex gels with physical and chemical crosslinkingBadani Prado, Rosa Maria 06 August 2021 (has links)
Gels are used in many applications ranging from bioengineering and pharmaceuticals to food technology and soft-robotics because of their tunable physical and mechanical properties. In many of these applications, the materials need to sustain large deformation. The microstructure of gels changes significantly at large strain values, causing a deviation in the stress responses from that at low strain. The desired mechanical responses of gels can be obtained by tuning their microstructure, therefore, the structure-property relationship for gels is required to be understood for their practical applications. This dissertation discusses two types of gels, one consists of chemical crosslinking and hydrophobic associations, and the other gel only consists of physical crosslinking. The microstructure of these two gel systems is investigated and related to their mechanical responses. The gel system with chemical and physical crosslinking mimics properties of biomaterials like resilin. Resilin is a protein-elastomer that enables biological species for power amplified activities by taking benefits of specific responses of hydrophilic and hydrophobic segments. Inspired by the microstructure and mechanical properties of resilin, a stretchable and resilient hydrogel was synthesized through a simple free radical polymerization technique. These gels retract from the stretched state to the original state with high speed over a short time, such behavior has not been frequently reported for synthetic hydrogels. This gel is also capable of performing a power-amplified activity like catapulting an object. In addition to retraction experiments, the mechanical properties of this gel were investigated in tensile and cyclic loading to determine their resilience. The hydrophobic polymer concentration affects the swelling behavior and mechanical responses such as stretchability and resilience. The second gel system considered here is a physically assembled ABA triblock copolymer dissolved in a B-selective solvent. Here, two different triblock copolymers with different concentrations were utilized. The real-time microstructural change was captured using a RheoSAXS setup with a high flux X-ray beam. The real-time microstructure of these gels subjected to temperature, varying oscillatory strain amplitude, and during relaxation after step strain was captured. This dissertation advances the understanding of the structure-property relationship of microstructurally complex gels towards their potential practical applications.
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Structure Property Relationships in Multilayered Thin Films: Mechanical and Gas Barrier ApplicationsHerbert, Matthew January 2015 (has links)
No description available.
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Regioselective Synthesis of Cellulose DerivativesXu, Daiqiang 14 August 2012 (has links)
Cellulose is the most abundant polysaccharide on earth and it is relatively a simple homopolymer with three hydroxyl groups, differing only subtly in reactivity. The position of substitution has a powerful influence on physical properties of cellulose derivatives. To better understand the structure and property relationships of cellulose derivatives, it is critical to have all homopolymers related to important cellulose ethers and esters available. However, regiocontrol in cellulose chemistry is still a difficult, mostly unconquered frontier.
In this dissertation, the main objective is to develop novel synthetic methods to synthesize regioselectively substituted cellulose derivatives including cellulose ethers and esters, and apply advanced characterization tools to understand structure and its influence on properties, which will give us deep insights into the composition of more random commercial derivatives, maximizing the content of advantageous monosaccharides. Several strategies to regioselectively synthesize cellulose derivatives are discussed in detail. The obtained regioselective cellulose derivatives were fully characterized analytically. Structure-property relationships of these regioselectively substituted cellulose derivatives were also studied. / Ph. D.
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