SMARTech Collection: School of Materials Science and Engineering Theses and Dissertations

Organic/inorganic nanostructured materials: towards synergistic mechanical and optical properties

Sun, 28 Jun 2009 22:58:59 GMT

Title: Organic/inorganic nanostructured materials: towards synergistic mechanical and optical properties

Authors: Gunawidjaja, Ray

Abstract: Two designs of inorganic/organic hybrid micro-structures are discussed: (1) silver nanowire reinforced layer-by-layer (LbL) polyelectrolyte composite film and (2) bimetallic silver-gold core-shell nanoparticles. In this work, zero-dimensional spherical gold nanoparticles (AuNPs), one-dimensional silver nanowires (AgNWs), and two-dimensional silver nanoplates (AgNPls) represent the inorganic component. Three-arm star polymer and polyelectrolytes represent the organic component. In the first design, the one-dimensional AgNWs serves as a mechanical reinforcement for the fabrication of mechanically isotropic and anisotropic polyelectrolyte composite films. The composite film is mechanically isotropic when the AgNWs are randomly oriented, and it is anisotropic when the AgNWs are unidirectionally oriented within the LbL polyelectrolyte matrix. Furthermore, above the AgNWs percolation threshold, the AgNWs reinforced LbL composite film is electrically conductive. Therefore, it can find application in ultrathin LbL film-based sensor. In the second design, the zero-dmensional AuNPs were assembled onto one-dimensional AgNWs and two-dimensional AgNPls by means of star polymer linker, or alternatively using polyelectrolytes via electrostatics interaction. The unique feature of these bimetallic silver-gold core-shell nanoparticles is their ability to greatly enhance electric field, due to the silver-gold intra-particle interaction. This allows it to serve as a single-nanoparticle surface enhanced Raman scattering (SERS) substrate for chemical sensing.

Noble and transition metal aromatic frameworks: synthesis, properties, and stability

Wed, 13 May 2009 22:58:59 GMT

Title: Noble and transition metal aromatic frameworks: synthesis, properties, and stability

Authors: Carson, Cantwell G.

Abstract: In the first section, the electrical conductivity of rhodium phenylene-diisocyanide polymer is reported to be 3.4E-11 S/cm. However, the conductivity also exhibits an inverse exponential decay in air with t = 8 days. This change is attributed to the oxidation of the isocyanide functional group to an isocyanate, leading to degradation in the long-range metal-metal bonding, the dominant conductivity mechanism. Using a more stable carboxylate ligand, the Cu terephthalate (TPA) system is studied and compared against the Mg, Co, Ni, and Zn terephthalates. A synthesis in N,N-dimethylformamide (DMF) is developed and large quantities of the Cu(TPA)DMF can be synthesized in air. The crystal structure of the Cu(TPA) DMF is shown to be in the C2/m spacegroup. Upon desolvation, the Cu(TPA) is shown to have a large surface area of 625 m2/g. The magnetic susceptibility of the Cu(TPA) indicates anti-ferromagnetic coupling between adjacent Cu centers in the same dimer. The thermal stability of the Zn, Ni, Co, and Mg terephthalates is shown to increase with decreasing symmetric carboxylate stretch in the IR. The magnetic susceptibilities of the Co and Ni terephthalates have paramagnetic behavior, with a Weiss temperature of T = -12.9 K and T = 8.8 for Co(TPA) DMF and Ni(TPA)DMF respectively. A heterometallic Zn-Cu terephthalate is synthesized with Cu concentrations ranging from 0 to 100%. Upon the addition of Cu, Zn-rich frameworks increase in surface area, change in thermal stability, and increase their solvent retention from 16% to 25%. Zn is shown to couple with Cu in the same dimer at a high rate, changing the behavior of the dimer from anti-ferromagnetic to paramagnetic. The Weiss temperature suggests weak ferromagnetic interaction.

The kinetics of incongruent reduction between sapphire and Mg-Al melts

Sun, 02 Apr 2006 22:58:59 GMT

Title: The kinetics of incongruent reduction between sapphire and Mg-Al melts

Authors: Liu, Yajun

Abstract: The kinetics of incongruent reduction between sapphire and oxygen-controlled Mg-Al melts was studied by measuring spinel-layer thickness, sample-weight change and sample-thickness change as a function of time at various temperatures. To eliminate the crucible contamination caused by impurities in commercial MgO crucibles, self-made high-purity MgO crucibles were achieved by gelcasting method, which is an attractive ceramic-forming technique for making high-purity ceramic parts. The oxygen-controlled alloys were obtained by the three-phase-equilibrium experiments at various temperatures. To avoid MgO formation, the oxygen-controlled alloys prepared at relatively lower temperatures were used for incongruent reaction at relatively higher temperatures. That is to say, the oxygen-controlled alloys prepared at 900°C, 1000°C, and 1100°C were used for spinel formation at 1000°C, 1100°C, and 1200°C, respectively. The experiments were conducted in a vertical furnace, and sapphire wafers were hung vertically in high-purity MgO crucibles so that the natural convection induced by the density change in the melt could be investigated. Experimental results obtained at 1000°C, 1100°C, and 1200°C showed that the spinel layer thickness on two kinds of sapphire wafers, namely {0001} and , followed orientation-independent parabolic kinetics, indicating the diffusion in spinel was one of the rate-limiting steps. In addition, the spinel layer thickness was not a function of position. The results of sample-thickness- change measurements also indicated that the effect of natural convection could be neglected. XPS, XRD, and TEM were also employed to characterize some samples in this study. Based on a simple model where the diffusion in spinel was the only rate-limiting step, the governing partial differential equations for diffusion and fluid dynamics were solved by the finite element method. The calculated theoretical parabolic constants at various temperatures were compared with these experimental results, and a good agreement was obtained. Some preliminary studies were also made on the morphologies of spinel particles at the nucleation stage. It was found that the triangular {111} faces of spinel particles were parallel to the surface of {0001} sapphire substrate. The product shape was consistent with the tetrahedron composed of {111} faces. The morphology of spinel particles on a sapphire substrate was more complicated in that the triangular {111} faces of spinel had to be inclined at a certain angle to the substrate in order to maintain the orientation relationship.

Controlled self-assembly of ito nanoparticles into aggregate wire structures in pmma-ito nanocomposites

Thu, 02 Apr 2009 22:58:59 GMT

Title: Controlled self-assembly of ito nanoparticles into aggregate wire structures in pmma-ito nanocomposites

Authors: Capozzi, Charles J.

Abstract: For polymer-matrix composites (PMCs) that contain insulating matrices and conducting fillers, the electrical properties of the PMCs are especially sensitive to the local concentration of the fillers in the matrix. For PMCs that have phase-segregated microstructures, better prediction of the properties is possible since enhanced control over the distribution of the filler in the matrix can be achieved. In this research, PMMA-ITO nanocomposites were chosen as the composite system in which to explore alternative microstructures, specifically highly phase-segregated microstructures. The microstructures were primarily controlled by varying the ITO particle size and concentration, and the fabrication parameters used to form the nanocomposites. The motivation for this research was to develop correlations between the microstructure and non-destructive measurements in order to improve the predictability of properties in percolating PMCs. As a result of this work, a novel phase-segregated microstructure was discovered, where ITO aggregate-wire structures self-assembled during the composite forming process. Structural analysis of the specimens was conducted primarily using transmission optical microscopy and scanning electron microscopy (SEM). Impedance spectroscopy and optical spectroscopy were the primary NDE characterization tools used for analyzing the variations among the specimens. Ultra-small angle x-ray scattering (USAXS) and stereological techniques were also used to describe the dimensions of the ITO aggregate-wire structures that self-assembled in the PMMA-ITO nanocomposites.