Patternable electrophosphorescent organic light-emitting diodes with solution-processed organic layers

Haldi, Andreas

08 August 2008

Organic light-emitting diodes (OLEDs) have drawn much attention in the last two decades. In recent years, the power efficiency of OLEDs has been increased to exceed the efficiency of fluorescent light bulbs. However, such high-efficiency devices are typically based on small molecules that have to be evaporated in vacuum. A much higher fabrication throughput and therefore lowered costs are expected if high-efficiency OLEDs were processed from solution. This thesis shows how solution-processed electrophosphorescent multilayer OLEDs can be achieved by starting with an evaporated three-layer device structure and replacing layer by layer with a solution-processed layer. First, the hole-transport layer was replaced by a polymer and high efficiencies were observed when using a hole-transport polymer with a high ionization potential and a low hole mobility. Then, the emissive layer was replaced by a copolymer consisting of hole-transport groups and emissive complexes in its side-chains. OLEDs with four different colors are shown where the orange devices showed the highest efficiency. The orange copolymer was further optimized by making changes to the chemical nature of the polymer, such as different molecular weight, different concentrations of the emissive complex and different linkers between the side-chains and the polymer backbone. Finally, a three-layer solution-processed OLED was fabricated by crosslinking the hole-transport and the emissive layer, and by spin-coating an electron-transport polymer on top. Moreover, using the photocrosslinking properties of the emissive layer, solution-processed multilayer OLEDs of two different colors were patterned using photolithography to fabricate a white-light source with a tunable emission spectrum. Furthermore, with more and more organic semiconductors being integrated into the circuitry of commercial products, good electrical models are needed for a circuit design with predictive capabilities. Therefore, a model for the example of an organic single-layer diode is introduced in the last chapter of this thesis. The model has been implemented into SPICE and consists of an equivalent circuit that is mostly based on intrinsic material properties, which can be measured in independent experiments. The model has been tested on four different organic materials, and good agreement between model and experimental results is shown.

Equivalent circuit

Copolymer

Phosphorescence

Solution-processing

OLED

Organic light-emitting diodes

Light emitting diodes

Electroluminescence

Organic thin films

Crosslinked polymers

Polymers

Swelling and Dye Adsorption Characteristics of Superabsorbent Polymers

Sharma, Tarun

January 2015

In the current study, SAPs of cationic monomer [2 - (Methacryloyloxy) ethyl] trimethylammonium chloride have been prepared by free radical solution polymerisation with different crosslinkers. They were subjected to repeated cycles of swelling and de-swelling in DI water and NaCl solution. The conductivity of the swelling medium was measured and related to the swelling/de-swelling characteristics of the SAPs. The swelling capacity was also determined in saline solution. The swelling and de-swelling processes were described by first-order kinetics. The SAPs exhibited varied swelling capacity for crosslinkers of the same functionality as well as different functionality. The SAPs were used to adsorb, the dye Orange G at different initial concentrations of the dye. The equilibrium adsorption data followed the Langmuir adsorption isotherms. The SAPs were also used to adsorb three other dyes, Congo red, Amido black and Alizarin cyanine green. They exhibited different adsorption capacity for different dyes. The adsorption phenomenon was found to follow first order kinetics. In the later part of the study, the co-monomers of [2 - (Methacryloyloxy) ethyl] trimethylammonium chloride with zwitter-ionic monomers [2-(Methacryloyloxy)ethyl]dimethyl-(3-sulfopropyl)ammonium hydroxide and [3-(Methacryloylamino)propyl]dimethyl(3-sulfopropyl)ammonium hydroxide inner salt were prepared in turns at two different concentrations. The effect of the addition of the zwitter-ionic monomers and their concentration of the swelling capacity and dye adsorption capacity was studied. There was no effect on the swelling capacity of the polymers due to either the species of the zwitter-ionic monomer or their concentration. However, there was a reduction in soluble content of the polymers. The dye adsorption capacity decreased at the higher concentration of the zwitter-ionic monomer.

Superabsorbent Polymers (SAPs)

Crosslinked Polymers

Polymerization

Cationic Superabsorbent Polymers

Superabsorbent Polymer Swelling

Superabsorbent Polymers-Dye Adsorption

Cationic-Zwitter Ionic Copolymers

Swelling Theory

Cationic SAP

Swelling and Dye

Chemical Engineering

Recycling of PVC and XLPE for High Impact Resistance in Spool Development

Granowski, Gregory A

05 1900

My work focuses on taking waste wire-grade PVC = poly(vinyl chloride) and waste XLPE = cross-linked polyethylene and recycle them into small wire/cable spool technology in order to reduce waste cost and reduce cost of spool production. The PVC and XLPE were provided by Encore Wire Corp. of McKinney, TX; they have also defined the standard to which I am comparing my results. The end goal is to incorporate as much PVC and XLPE into the spools while maintaining material toughness, impact resistance, as well as cost-effectiveness in the implementation of the waste materials. The work has been divided into two primary sections, the first is focused on improving material strength through the addition of ceramic fillers. The second section is focused on adding PVC and XLPE into a stronger and highly cohesive polymer matrix and optimizing the concentration of the waste products. Since XLPE is non-polar while PVC is strongly polar, compatibilizers such as CPE (chlorinated polyethylene) and MA-DCP (maleic anhydride with dicumyl peroxide) were used to improve interactions between polar and non-polar constituents. Testing involved the tensile mechanical properties, tribology and thermal properties, namely dynamic mechanical analysis (DMA) and evaluation of thermal degradation by thermogravimetric analysis (TGA). Combining PVC and XLPE together is not economically feasible with current compatiblizers. At the same time, introduction of PVC waste or XLPE waste with sufficient properties of the resulting composites is doable.

Polymer

recycling

PVC, ABS, PP, PE

Engineering, Materials Science

Polyvinyl chloride -- Recycling.

Crosslinked polymers -- Recycling.

Cables -- Mechanical properties.

Cables -- Thermal properties.

Molecular Imprinting Technology Towards the Development of a Novel Biosensor

Avalos, Abraham

January 2014

No description available.

Biomedical Engineering

Molecular imprinting

protein detection

protein imprinting

surface plasmon resonance

crosslinked polymers

functional monomers

template removal

protein-polymer interaction

artificial antibody

Dependence of physical and mechanical properties on polymer architecture for model polymer networks

Guo, Ruilan

27 February 2008

Effect of architecture at nanoscale on the macroscopic properties of polymer materials has long been a field of major interest, as evidenced by inhomogeneities in networks, multimodal network topologies, etc. The primary purpose of this research is to establish the architecture-property relationship of polymer networks by studying the physical and mechanical responses of a series of topologically different PTHF networks. Monodispersed allyl-terminated PTHF precursors were synthesized through ¡°living¡± cationic polymerization and functional end-capping. Model networks of various crosslink densities and inhomogeneities levels (unimodal, bimodal and clustered) were prepared by endlinking precursors via thiol-ene reaction. Thermal characteristics, i.e., glass transition, melting point, and heat of fusion, of model PTHF networks were investigated as functions of crosslink density and inhomogeneities, which showed different dependence on these two architectural parameters. Study of freezing point depression (FPD) of solvent confined in swollen networks indicated that the size of solvent microcrystals is comparable to the mesh size formed by intercrosslink chains depending on crosslink density and inhomogeneities. Relationship between crystal size and FPD provided a good reflection of the existing architecture facts in the networks. Mechanical responses of elastic chains to uniaxial strains were studied through SANS. Spatial inhomogeneities in bimodal and clustered networks gave rise to ¡°abnormal butterfly patterns¡±, which became more pronounced as elongation ratio increases. Radii of gyration of chains were analyzed at directions parallel and perpendicular to stretching axis. Dependence of Rg on ¦Ë was compared to three rubber elasticity models and the molecular deformation mechanisms for unimodal, bimodal and clustered networks were explored. The thesis focused its last part on the investigation of evolution of free volume distribution of linear polymer (PE) subjected to uniaxial strain at various temperatures using a combination of MD, hard sphere probe method and Voronoi tessellation. Combined effects of temperature and strain on free volume were studied and mechanism of formation of large and ellipsoidal free volume voids was explored.

Free volume distribution

Freezing point depression

Thermal characteristics

Molecular deformation

Inhomogeneities

Unimodal bimodal clustered architecutres

Model PTHF networks

Polymer networks

Topology

Materials Mechanical properties

Materials Thermal properties

Crosslinked polymers