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This book explains different magnetic resonance (MR) techniques and uses different combinations of these techniques to analyze defects in semiconductors and nanostructures. It also introduces novelties such as single defects MR and electron-paramagnetic-resonance-based methods: electron spin echo, electrically detected magnetic resonance, optically detected magnetic resonance and electron-nuclear double resonance – the designated tools for investigating the structural and spin properties of condensed systems, living matter, nanostructures and nanobiotechnology objects. Further, the authors address problems existing in semiconductor and nanotechnology sciences that can be resolved using MR, and discuss past, current and future applications of MR, with a focus on advances in MR methods. The book is intended for researchers in MR studies of semiconductors and nanostructures wanting a comprehensive review of what has been done in their own and related fields of study, as well as future perspectives.
Different magnetic resonance (MR) methods and their applications in solids (e.g. semiconductors and nanostructures) are the focus of this work. Techniques and combinations thereof are explained and used to analyze defects in semiconductors and nanostructures. Presented for the first time are novelties such as single defects MR as well as state-of-art high-frequency pulse methods: EPR, ODMR, ENDOR. An overview of MR methods currently used to study defects, such as electron paramagnetic resonance (EPR), optically detected magnetic resonance (ODMR), electron-nuclear double resonance (ENDOR) etc. is provided. Problems existing in semiconductor and nanotechnology sciences which are resolved by MR are given. The past and current state and perspectives of application of MR are provided with emphasis on advances in MR methods. Intended for researchers in MR studies of semiconductors and nanostructures wanting a comprehensive review of what has been done in their and related fields of studies as well as future perspectives.
In the last couple of decades, high-performance electronic and optoelectronic devices based on semiconductor heterostructures have been required to obtain increasingly strict and well-defined performances, needing a detailed control, at the atomic level, of the structural composition of the buried interfaces. This goal has been achieved by an improvement of the epitaxial growth techniques and by the parallel use of increasingly sophisticated characterization techniques and of refined theoretical models based on ab initio approaches. This book deals with description of both characterization techniques and theoretical models needed to understand and predict the structural and electronic properties of semiconductor heterostructures and nanostructures. - Comprehensive collection of the most powerful characterization techniques for semiconductor heterostructures and nanostructures - Most of the chapters are authored by scientists that are among the top 10 worldwide in publication ranking of the specific field - Each chapter starts with a didactic introduction on the technique - The second part of each chapter deals with a selection of top examples highlighting the power of the specific technique to analyze the properties of semiconductors
Semiconductor nanostructures are attracting a great deal of interest as the most promising device with which to implement quantum information processing and quantum computing. This book surveys the present status of nanofabrication techniques, near field spectroscopy and microscopy to assist the fabricated nanostructures. It will be essential reading for academic and industrial researchers in pure and applied physics, optics, semiconductors and microelectronics. - The first up-to-date review articles on various aspects on quantum coherence, correlation and decoherence in semiconductor nanostructures
This book focuses on the main aspects of electron and nuclear spin dynamics in semiconductor nanostructures. It summarizes main results of theoretical and experimental studies of interactions in spin systems, effects of ultrafast spin manipulation by light, phenomena of spin losses, and the physics of the omnipresent spin noise.
Conjugated polymeric materials and their nanocomposites are widely used for the creation of alternative sources of renewable energy, cell phone screens, mobile gadgets, video players and OLED-TV, as well as organic diodes, transistors, sensors, etc. with field-dependent and spin-assisted electronic properties. Multifrequency EPR Spectroscopy methods can help researchers optimize their structural, magnetic and electronic properties for the creation of more efficient molecular devices. This book will acquaint the reader with the basic properties of conjugated polymers, the fundamentals of EPR Spectroscopy, and the information that can be obtained at different wavebands of EPR spectroscopy.
As the global community confronts challenges in energy, environment, health, agriculture, industry, and construction, the significance of sustainable materials becomes paramount. The looming specter of resource depletion necessitates a paradigm shift, urging researchers and engineers to anticipate future needs and forge materials that align with evolving requirements. Next Generation Materials for Sustainable Engineering underscores the urgency of conserving resources and provides a blueprint for achieving this through judicious and sustainable use. From polymers to alloys, nanocomposites to biomaterials, this book traverses the expansive landscape of materials, deciphering their structures and properties with an eye toward sustainability. The relentless pursuit of innovation in synthesis protocols takes center stage, unveiling pathways to creating novel materials. The chapters dedicated to specific material applications, such as spintronics, nanowires, phase change materials, and nanocomposites, offer a detailed panorama of the latest advancements. This book bridges the gap between theoretical understanding and practical applications by exploring materials for renewable energy, electronic devices, artificial photosynthesis, lithium-sulfur batteries, supercapacitors, and biomedical applications. The book serves as a beacon for academicians, researchers, and material scientists, guiding them through state-of-the-art developments, emerging trends, and challenges in material science and engineering.
The book presents invited reviews and original short notes with recent results obtained in fabrication study and application of nanostructures, which are promising for new generations of electronic and optoelectronic devices.
Focusing on the fundamental principles of nanoscience and nanotechnology, this carefully developed textbook will equip students with a deep understanding of the nanoscale. • Each new topic is introduced with a concise summary of the relevant physical principles, emphasising universal commonalities between seemingly disparate areas, and encouraging students to develop an intuitive understanding of this diverse area of study • Accessible introductions to condensed matter physics and materials systems provide students from a broad range of scientific disciplines with all the necessary background • Theoretical concepts are linked to real-world applications, allowing students to connect theory and practice • Chapters are packed with problems to help students develop and retain their understanding, as well as engaging colour illustrations, and are accompanied by suggestions for additional reading. Containing enough material for a one- or two-semester course, this is an excellent resource for senior undergraduate and graduate students with backgrounds in physics, chemistry, materials science and electrical engineering.
The book presents invited reviews and original short notes with recent results obtained in fabrication study and application of nanostructures, which are promising for new generations of electronic and optoelectronic devices.Recent developments in nanotechnology, nanoelectronics, spintronics, nanophotonics, nanosensorics and nanobiology are presented.