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Resumen de Radical and non-radical carbazole derivatives formolecular electronics. Molecular Glasses and Liquid Crystals.

Sonia Castellanos Ortega

  • Molecular electronics is an emergent area of the new technologies related to the use of organic and biological materials in optoelectronic and electronic devices. Among the materials used in electronic applications, low molecular weight materials, or molecular materials, became of great interest in the last years, due to the advantages they present in front of the traditional polymeric materials, such as, easier synthesis, purification and characterization, and a better processability.The objectives of this thesis were the preparation and characterization of new molecular materials bearing the carbazole heterocycle (part 1), the evaluation of their charge transport properties (part 2) and their application in electronic devices, for the ones that presented the required properties (part 3).1. Materials. New compounds belonging to two groups were prepared: non-radical carbazole derivatives, mainly based in the N-phenylcarbazole aromatic core, and radical carbazole derivatives, based on structures that combine the unit tris(2,4,6-trichlorophenyl)methyl radical and the carbazole fragment. Depending on the morphology of their solid state, the sought materials were classified in liquid crystals and molecular glasses, that is, molecular materials showing glassy states. The light absorption, photoluminescence and electrochemical properties of the different derivatives and their solid state phases were determined by different techniques. The studies proved that the mesogens deriving from N-phenylcarbazole with 7 alkoxyl chains presented ordered columnar phases. These columnar mesophases were stabilized by doping with 2,4,7-trinitrofluorenone and destabilized by the presence of terminal carboxílic acids. However, the derivatives with the same aromatic core but only 4 alkoxyl chains formed lamelar phases (layers). The analogous N-phenylcarbazole derivatives with 7 and 4 methoxy groups, though, presented glassy states. Derivatives of the 1,3,5-tris(N-carbazolyl)benzene bearing tricyanovinyl moieties, which showed reversible reductions -an opposite behavior to the 1,3,5-tris(N-carbazolyl)benzene hole-transporting precursor- and high thermal stability, were prepared. The first discotic radical bearing the unpaired electron in the center of the aromatic core and showing columnar liquid-crystalline phases was prepared. A change in the magnetic behavior due to changes in the molecular disposition was detected in this radical compound at temperatures under rt. and over rt.2. Charge transport properties. The most representative glassy molecules and columnar liquid crystals were evaluated as semiconductors. The used techniques were the xerographic time-of-flight (XTOF), for molecular glasses, and the time of flight (TOF), for liquid crystals. The obtained results indicated that some of the radical molecular glasses presented charge transport with high mobility values for both holes and electrons (bipolar materials), whereas some of the non-radical molecular glasses showed moderate hole mobility values by XTOF measurements. The charge mobility of liquid crystals could not be evaluated due to the highly dispersive regime of their charge transport. A methodology to attain homeotropic alignment of the radical mesogen columns within the measure cells was found.3. Electronic devices. Organic thin film transistors (OTFTs) of two radical compounds, as well as of an N-phenylcarbazole derivative were built. A p-type semiconductor behavior was observed in some cases. Schottky type and bulk-heterojunction organic photovoltaic devices (OPVs) with N-carbazolylTTM radical were prepared. In these devices the radical adduct worked as a donor material. Acceptable open circuit voltage values and symbathic behaviors were observed in the measured cells.


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