This book focuses on research related to ionic conducting (e.g., protons, oxygen ions) materials and devices. Contributions range from fundamental materials R&D, to characterization, to materials for batteries, sensors, membranes, supercapacitors and fuel cells. Special emphasis is given to miniaturized solid-oxide fuel cells (micro-SOFCs), from fundamental materials studies which are still very much needed for this application, to the development of devices. Innovative concepts for energy storage are also discussed.
Solid Oxide Fuel Cells (SOFCs) operate at high temperatures allowing more fuel flexibility and also useful heat output and so increase total efficiency, but does give some interesting engineering challenges. Solid Oxide Fuels Cells: Facts and Figures provides clear and accurate data for a selection of SOFC topics from the specific details of Ni cermet anodes, chemical expansion in materials, and the measuring and modelling of mechanical stresses, to the broader scope of the history and present design of cells, to SOFC systems and the future of SOFC. Celebrating Ulf Bossel’s work on Solid Oxide Fuel Cells, and especially his running of the European Fuel Cell Forum, Solid Oxide Fuels Cells: Facts and Figures covers important topics on the way including intermediate temperature fuel cells, metal supported fuel cells and both new materials and engineering solutions to some of the challenges of getting SOFC to market. The chapters are based on the special plenary talks given by some of the most respected and talented people in the field at the 2010 European SOFC Forum in Luzern and the title for this book comes from the report produced by Ulf for the IEA “Final Report on SOFC Data, Facts and Figures”, Swiss Federal Office of Energy, Berne, 1992. The comprehensive nature of Solid Oxide Fuels Cells: Facts and Figures makes it a key resource of SOFC topics for students, lecturers, researchers and industry practitioners alike.
Introduction to Solid State Ionics: Phenomenology and Applications presents a pedagogical, graduate-level treatment of the science and technology of superionic conductors, also known as fast ion conductors or solid electrolytes. Suitable for physics, materials science, and engineering researchers and students, the text emphasizes basic physics and
This book is a sequel to the first volume of The Chemistry of Nanostructured Materials. It covers the most exciting developments in the nanostructured materials field for the past five to ten years, with a particular focus on their applications in energy conversion and energy storage. Prominent authors of recognized authority in the field contribute their expertise in the review chapters.
Microelectromechanical systems (MEMS) have transitioned from a technology niche to a role of major industrial significance. The worldwide market for MEMS is now approximately $10 billion, and the total value of systems enabled by MEMS is several orders of magnitude higher than this figure. As the market has grown, the material and process sets have broadened and departed from their semiconductor roots. In addition to engineering materials, there is now great interest in integrating multifunctional nanomaterials, smart materials and biomaterials within MEMS/NEMS to enhance functionality, performance and reliability. The opportunities created by this integration have generated a vibrant research community working on new materials and processes. This book reflects the breadth of topics currently under investigation in the field. Novel materials and accompanying processes are discussed, as are more conventional materials and processes. Consistent themes are the need for accurate material property assessment at the relevant length scales and for suitable metrology tools to support the introduction of new materials.