The mechanical properties of small volumes of materials (such as thin films and patterned structures) can be very different from larger volumes, especially in the area of dislocation behavior. This text contains a selection of 31 papers from the April 2001 symposium devoted to new methods of dislocation modeling. Topics include mechanisms of plastic deformation in heteroepitaxial, multilayered, and polycrystalline thin films; as well as in 3D mesostructures such as epitaxial islands, semiconducting devices, and microcrystallites. The organizers of the symposium had the particular aim of stimulating exchange between experimental work, theoretical modeling, and numerical simulations. Annotation copyrighted by Book News Inc., Portland, OR.
The MRS Symposium Proceeding series is an internationally recognised reference suitable for researchers and practitioners. This book, first published in 2001, focuses on the interactions between different mechanisms of microstructure evolution and film-growth conditions.
Oxide materials are rapidly impacting a broad spectrum of optoelectronic applications, from energy conservation to communications and computer memory. Developing a better understanding of the relationships between transport and microstructural phenomena is critical to the continued evolution of these applications. This volume reports on new materials and improved growth of films, and offers a much deeper level of understanding of the key determinates affecting the electro-optical performance of oxide-based devices. Transparent conducting oxides (TCOs), with a focus on p-type materials, are highlighted. One of the most exciting results in the TCO area is the report of CulnO2, where the material was doped n-type with Sn4+ and p-type with Ca2+. This is the first proven TCO system where homojunctions should be possible. Ferroelectric materials are another family of materials emerging in the area of DRAM and frequency-agile microwave electronics. A number of papers focus on the methods of controlling the interfacial properties of ferroelectric materials such as BaSrTiO3 on a variety of substrates. A number of groups are approaching atomic-level control of interfaces, allowing for the deposition of high-quality materials on substrates as diverse as Si and MgO. Embedded strain from the growth process for ferroelectric materials and other oxide systems is also demonstrated to be a critical determinate of the film. And a new model for ferroelectric materials indicates that a nanopolar reorientation transition may be responsible for the marked increase in dielectric tuning for nonstressed films. Topics include: transparent conducting oxides; transport and microstructural phenomena in oxide electronics; oxide-based devices; ferroelectric materials; and oxide thin-film growth.
The MRS Symposium Proceeding series is an internationally recognised reference suitable for researchers and practitioners. Much like earlier books in the series, this collection of papers, first published in 2001, brings together the materials science community and the characterization techniques that use synchrotron radiation.
Solid-state chemistry is an interdisciplinary field, and these researchers share the common challenge of understanding, controlling, and predicting the structures and properties of solids at the atomic level. This book provides a forum for the presentation of recent advances in the solid-state chemistry of inorganic materials and the impact of these advances on the development of practical applications. Topics include: crystal chemistry of complex systems; dielectrics, crystal chemistry, glasses and electrical transport; transport properties/metal-insulator systems; magnetism and manganates; new materials - meso/nanoporous materials; micro/meso/ nanoporous materials - inorganic/organic hybrids; synthesis, new methods and new materials; solid-state ionics, battery materials, thermopower and optical materials; solid-state ionics, battery materials and energy storage; and thermopower, themal expansion and optical materials. A highlight is a section dedicated to Professor J.M. Honig in recognition of his many contributions to the discipline of solid-state chemistry and his stewardship of the Journal of Solid-State Chemistry.