Katharina Al-Shamery - Böcker

This jaw-dropping window on the future is the first comprehensive overview of the fabrication, fundamental properties, and applications of a new class of nanoscaled organic materials. These materials offer incredible scope to scientists wanting to exploit their optical and electronic properties and offer the potential to create a new generation of tiny devices with powerful applications. Altogether, this book offers a unique integration of organic materials science basics, nanostructured organic materials fabrication, and device applications.

In this volume, concepts of nonlinear dynamics and self-organization are applied to topics in materials sciences with emphasis on semiconductors, soft matter, and biomaterials. The questions addressed include how to compare ordering phenomena under nonequilibrium situations, usually called self-organized structures, with those arising under situations close to equilibrium via selfassembly. Analogies are pointed out, differences are characterized, and efforts made to discover common features in the mechanistic description of those phenomena. Of major importance is the question of the role of spatial and temporal order, in particular, the application of concepts developed on macroscopic and microscopic scales to structure formation occurring on nanoscales, which occupies the focus of interest on the frontiers of science.

Organic semiconductors are a central topic of advanced materials research. The book is aiming at bridging the gap between the development and production of devices and basic research on thin film characterisation using cutting-edge techniques in surface and interface science. Topics involve organic molecular-based sensors; interfaces in organic diodes and transistors; mobility in organic field effect transistors and space charge problems; integration of optoelectronic nanostructures; nonlinear optical properties of organic nanostructures; the wetting layer problem; how to get from functionalized molecules to nanoaggregates; optical, electrical and mechanical properties of organic nanofibers as well; as near field investigations of organic thin films.

This jaw-dropping window on the future is the first comprehensive overview of the fabrication, fundamental properties, and applications of a new class of nanoscaled organic materials. These materials offer incredible scope to scientists wanting to exploit their optical and electronic properties and offer the potential to create a new generation of tiny devices with powerful applications. Altogether, the book offers a unique integration of organic materials science basics, nanostructured organic materials fabrication, and device applications.

In this volume, concepts of nonlinear dynamics and self-organization are applied to topics in materials sciences with emphasis on semiconductors, soft matter, and biomaterials. The questions addressed include how to compare ordering phenomena under nonequilibrium situations, usually called self-organized structures, with those arising under situations close to equilibrium via selfassembly. Analogies are pointed out, differences are characterized, and efforts made to discover common features in the mechanistic description of those phenomena. Of major importance is the question of the role of spatial and temporal order, in particular, the application of concepts developed on macroscopic and microscopic scales to structure formation occurring on nanoscales, which occupies the focus of interest on the frontiers of science.