Photovoltaic technology has now developed to the extent that it is close to fulfilling the vision of a “solar-energy world,” as devices based on this technology are becoming efficient, low-cost and durable. This book provides a comprehensive treatment of thin-film silicon, the most prevalent PV material, in terms of its semiconductor nature, starting out with the physical properties, but concentrating on device applications. A special emphasis is given to amorphous silicon and microcrystalline silicon as photovoltaic materials, along with a model that allows these systems to be physically described in the simplest manner possible, thus allowing the student or scientist/engineer entering the field of thin-film electronics to master a few basic concepts that are distinct from those in the field of conventional semiconductors. The main part of the book deals with solar cells and modules by illustrating the basic functioning of these devices, along with their limitations, design optimization, testing and fabrication methods. Among the manufacturing processes discussed are plasma-assisted and hot-wire deposition, sputtering, and structuring techniques.

Introduction - Basic Properties of Amorphous Silicon - Basic Properties of Hydrogenated Microcrystalline Silicon - Theory of Solar Cell Devices - Tandem and Multi-Junction Solar Cells - Module Fabrication and Performance - Examples of Solar Cells Applications - Thin-Film Electronics

With the challenges our society faces concerning energy and the environment, it is particularly vital to develop a more rational use of our resources, both renewable and non-renewable. A sustainable use of the available resources is only possible if engineers can rely on coherent indicators, among which the exergy efficiency is bound to play a major role.

Solidication is one of the oldest processes for producing complex shapes for applications ranging from art to industry, and it remains as one of the most important commercial processes for many materials. Since the 1980's, numerous fundamental developments in the understanding of solidication processes and microstructure formation have come from both analytical theories and the application of computational techniques using commonly available powerful computers.

In recent years, the transport simulation of large road networks has become far more rapid and detailed, and many exciting developments in this field have emerged. In this perspective, the authors describe the simulation of automobile, pedestrian and rail traffic, coupled to new applications, such as the embedding of traffic simulation into driving simulators, to give a more realistic environment of driver behavior surrounding the subject vehicle.