Inkjet printing of organic transistor devices

In the last two decades inkjet printing passed from the field of graphic art and newspaper industry to that of organic and flexible electronics, as a manufacturing tool, becoming a major topic in scientific research. The appeal of this kind of technology is mainly due to its low cost, non-contact and additive approach, which makes it surely the most promising technique over the other technologies of Printed Electronics. The focus of this thesis is the optimization of the printing process, employing a piezo- electric Drop-on-Demand inkjet printer, for the realization of organic transistors on highly flexible plastic substrates, and their development in more complex systems for sensing applications. Indeed, all the devices realized have been investigated by means of electrical measures and spectroscopic techniques, in order to assess their performances and, consequently, to evaluate the reliability of inkjet printing as fabrication technique for such devices. In the first chapter a general introduction to the field of Printed Electronics, with particular focus on inkjet printing technique, is given. The second chapter provides informations concerning the fabrication characterization procedure followed, including a detailed description of the inkjet printing technology used, a report about the main physical and chemical properties of the materials employed, the explanation of the inkjet printing procedure for each material used in this thesis (as the printing parameters optimization and the approach for the resolution of some technical issues); finally also a brief description of the experimental techniques employed in order to characterize the devices is given. The third chapter is fully dedicated to the results concerning the fabrication and the characterization of all-Organic ElectroChemical Transistors (OECTs), while in the fourth chapter the results about inkjet printed Organic Field Effect Transistors (OFETs) are discussed. Finally, a brief chapter reports a summary of the main results achieved

EUROSENSORS XVII : book of abstracts

Fundação Calouste Gulbenkien (FCG).Fundação para a Ciência e a Tecnologia (FCT)

Acoustic Waves

The concept of acoustic wave is a pervasive one, which emerges in any type of medium, from solids to plasmas, at length and time scales ranging from sub-micrometric layers in microdevices to seismic waves in the Sun's interior. This book presents several aspects of the active research ongoing in this field. Theoretical efforts are leading to a deeper understanding of phenomena, also in complicated environments like the solar surface boundary. Acoustic waves are a flexible probe to investigate the properties of very different systems, from thin inorganic layers to ripening cheese to biological systems. Acoustic waves are also a tool to manipulate matter, from the delicate evaporation of biomolecules to be analysed, to the phase transitions induced by intense shock waves. And a whole class of widespread microdevices, including filters and sensors, is based on the behaviour of acoustic waves propagating in thin layers. The search for better performances is driving to new materials for these devices, and to more refined tools for their analysis

Laser Systems for Applications

This book addresses topics related to various laser systems intended for the applications in science and various industries. Some of them are very recent achievements in laser physics (e.g. laser pulse cleaning), while others face their renaissance in industrial applications (e.g. CO2 lasers). This book has been divided into four different sections: (1) Laser and terahertz sources, (2) Laser beam manipulation, (3) Intense pulse propagation phenomena, and (4) Metrology. The book addresses such topics like: Q-switching, mode-locking, various laser systems, terahertz source driven by lasers, micro-lasers, fiber lasers, pulse and beam shaping techniques, pulse contrast metrology, and improvement techniques. This book is a great starting point for newcomers to laser physics