Applications of organic semiconductors: from nanostructured solar cells to ionizing radiation dosimeters.

Organic semiconductors have atracted much attention from the scientific community and from the industry. The large interest is divided between the rich number of basic physical and chemical phenomena to be investigated and the great technological potential for application in different areas, such as light emitting diodes (OLEDs), solar cells, photodiodes, transistors, biosensors, ionizing radiation sensors, among others. The subject of this work was to contribute to a deeper understanding of two areas of application, both related to the interaction of electromagnetic radiation with matter: solar cells and gamma ray dosimetry. In the area of solar cells, the lack of materials absorbing in the near infrared (NIR) and the poor control of the morphology of the active films are limiting factor to increasing device efficiency. Therefore both this aspects were explored. A new concept of organic solar cell fabrication was presented based on the anostructuration of polymeric thin films. The methodology is based on phase separation of polymer blends during spin-coating followed by the selective removal of one component. This allows the controlled formation of thin films with characteristic features varying from a few nanometers to micrometers. The effects of molecular weigth, solvent and relative composition were investigated and discussed based on the analysis of AFM images and phase separation models. Devices using structured MEH-PPV layers, covered by C60 were fabricated and showed white light power conversion efficiencies (?) up to 400 % higher than a flat double layer device. Monochromatic ? achieved 2.95 % (480 nm), three times higher than the best reported value for this material combination so far. Using cyanine dyes, photovoltaic devices and photodiodes active in the NIR (~1000 nm) were demosntrated and an important effect of movable ions present in the dyes was observed. Finally, the application of a polymerized dye as gamma ray dosimeter was demonstrated. The operation range can be altered by varying the concentration of polymer in solution, and are useful in the range of low dose food irradiation. (AU)