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This book focuses on the fundamental phenomena at nanoscale. It covers synthesis, properties, characterization and computer modelling of nanomaterials, nanotechnologies, bionanotechnology, involving nanodevices. Further topics are imaging, measuring, modeling and manipulating of low dimensional matter at nanoscale. The topics covered in the book are of vital importance in a wide range of modern and emerging technologies employed or to be employed in most industries, communication, healthcare, energy, conservation , biology, medical science, food, environment, and education, and consequently have great impact on our society.
The purpose of this book is two fold. First to explain the properties of low dimensional solids such as electronic, vibrational and magnetic structure in terms of simple models. These are used to account for the properties of three dimensional materials providing an elementary introduction to the physics of low dimensional materials. The second objective is to discuss the properties of newer low dimensional materials not made of carbon. These are now the subject of research and describe various phenomena in them such magnetism and superconductivity.
Low Dimensional Materials: Bridging the Fundamental Principles to Practice Applications provides an overview of research on low-dimensional materials, devices, and their applications. There are seven chapters in the book, starting from the basic quantum theory in chapter one, to the control and characterization of the unique structures (chapters two and four), to the relation of the physical and chemical properties with structures (chapter five), and to the practical and promising applications in energy, information, and health (chapter six), before conclusions and future outlook in chapter seven. - Discusses the whole field of low-dimensional materials, from quantum mechanics and low dimensional effects to structure-property relations, various methods of fabrication and assembly techniques, and a characterization of atomic and interface structures - Covers a wide range of topics, making it a 'map' for readers to understand the fundamentals of low-dimensional materials - Written with a 'bottom-up approach, with a solid foundation of quantum mechanics, thermodynamics, and energy transport in low-dimensional systems
This book discusses the essential properties of carbon nanotubes and 2D graphene systems. The book focuses on the fundamental excitation properties of a large range of graphene-related materials, presenting a new theoretical framework that couples electronic properties and e-e Coulomb interactions together in order to thoroughly explore Coulomb excitations and decay rates in carbon-nanotube-related systems.
This volume contains papers presented at the NATO Advanced Research Workshop (ARW) Dynamic Interactions in Quantum Dot Systems held at Hotel Atrium in Puszczykowo, near Poznan, Poland, May 16-19,2002. The term low-dimensional systems, which is used in the title of this volume, refers to those systems which contain at least one dimension that is intermediate between those characteristic ofatoms/molecules and those ofthe bulk material. Depending on how many dimensions lay within this range, we generally speak of quantum wells, quantum wires, and quantum dots. As such an intermediate state, some properties of low-dimensional systems are very different to those of their molecular and bulk counterparts. These properties generally include optical, electronic, and magnetic properties, and all these are partially covered in this book. The main goal of the workshop was to discuss the actual state of the art in the broad area ofnanotechnology. The initial focus was on the innovative synthesis of nanomaterials and their properties such as: quantum size effects, superparamagnetism, or field emission. These topics lead us into the various field based interactions including plasmon- magnetic spin- and exciton coupling. The newer, more sophisticated methods for characterization of nanomaterials were discussed, as well as the methods for possible industrial applications. In general, chemists and physicists, as well as experts on both theory and experiments on nanosized regime structures were brought together, to discuss the general phenomena underlying their fields ofinterest from different points ofview.
Learn about the most recent advances in 2D materials with this comprehensive and accessible text. Providing all the necessary materials science and physics background, leading experts discuss the fundamental properties of a wide range of 2D materials, and their potential applications in electronic, optoelectronic and photonic devices. Several important classes of materials are covered, from more established ones such as graphene, hexagonal boron nitride, and transition metal dichalcogenides, to new and emerging materials such as black phosphorus, silicene, and germanene. Readers will gain an in-depth understanding of the electronic structure and optical, thermal, mechanical, vibrational, spin and plasmonic properties of each material, as well as the different techniques that can be used for their synthesis. Presenting a unified perspective on 2D materials, this is an excellent resource for graduate students, researchers and practitioners working in nanotechnology, nanoelectronics, nanophotonics, condensed matter physics, and chemistry.
The author develops the effective-mass theory of excitons in low-dimensional semiconductors and describes numerical methods for calculating the optical absorption including Coulomb interaction, geometry, and external fields. The theory is applied to Fano resonances in low-dimensional semiconductors and the Zener breakdown in superlattices. Comparing theoretical results with experiments, the book is essentially self-contained; it is a hands-on approach with detailed derivations, worked examples, illustrative figures, and computer programs. The book is clearly structured and will be valuable as an advanced-level self-study or course book for graduate students, lecturers, and researchers.
Low-dimensional Materials and Applications systematically introduces the preparation and performance of low-dimensional materials, such as carbon fiber, carbon nanotubes, graphene etc, as well as their applications in environmental pollution control, electronics, coating industry and defense technologies. Written with a practical focus and containing abundant examples, it is well suited for both researchers and engineers.
This text is a first attempt to pull together the whole of semiconductor science and technology since 1970 in so far as semiconductor multilayers are concerned. Material, technology, physics and device issues are described with approximately equal emphasis, and form a single coherant point of view. The subject matter is the concern of over half of today's active semiconductor scientists and technologists, the remainder working on bulk semiconductors and devices. It is now routine to design and the prepare semiconductor multilayers at a time, with independent control over the dropping and composition in each layer. In turn these multilayers can be patterned with features that as a small as a few atomic layers in lateral extent. The resulting structures open up many new ares of exciting solid state and quantum physics. They have also led to whole new generations of electronic and optoelectronic devices whose superior performance relates back to the multilayer structures. The principles established in the field have several decades to go, advancing towards the ultimate of materials engineering, the design and preparation of solids atom by atom. The book should appeal equally to physicists, electronic engineers and materials scientists.
The past few decades have seen an explosive increase in our ability to create nanostructures and nanosystems with a great degree of control, using a diversity of techniques. This ability has been accompanied by a similar enhancement in our ability to characterize structures and systems at the nanoscale. This book provides a broad overview of those nanostructures and nanosystems (together termed Nanotechnology). It covers structural characteristics and properties of nanostructures, nanofabrication techniques, methods for characterizing nanostructures, and applications for nanomaterials. The book also provides a thought-provoking assessment of the possible implications of nanotechnology in society, and likely future trends. Nanotechnology: A Crash Course is accessible to a wide readership and will meet the immediate needs of college graduates, doctoral students, professors, and researchers alike, who are looking for a quick yet inclusive grasp of this cutting-edge technology.Contents: To the Reader; Nomenclature; Low-Dimensional Structures; Properties of Nanostructures; Nanofabrication; Characterization of Nanostructures and Nanomaterials; Nanomaterials and Applications; Future Prospects; Index Suppose that you recently graduated with a B.S. degree in science or engineering and will commence your first professional employment tomorrow. Earlier this afternoon, your manager called to ask if you know something about nanotechnology, so that tomorrow you can begin developing an internal proposal for your division. But either your college did not offer a course on nanotechnology or you decided not to take one. You need a crash course in nanotechnology, just to get you off the ground.Suppose that you are a doctoral student in a department whose candidacy examination requires you to write a 5 10-page research proposal on an emerging topic assigned by the faculty committee. Suppose that your assigned topic intersects with nanotechnology, but all that you know about nanotechnology came from a couple of hour-long graduate seminars that you attended the previous semester.You need a crash course in nanotechnology, not only to write an impressive introduction but also to acquaint yourself with terminology to conduct efficient searches on Google Scholar, Web of Science, Scopus, etc. Suppose that you are a post-doctoral researcher at either an academic or an industrial research institution. Your supervisor has asked you to advise a shining undergraduate student for a summer project in nanotechnology, although the focus of your own research is elsewhere. You need a crash course in nanotechnology, to start the youngster off in a promising direction. Suppose that you are a new assistant professor. Your departmental head advises that your research proposal to a government program to assist new faculty members begin research programs lacks that wow factor that would virtually guarantee success. Put in a nano angle, you are told. You need a crash course in nanotechnology, to clothe your proposal in the glory of nano. Suppose that you are a middle-aged professor undergoing a midlife crisis. Instead of changing your family or lifestyle, you may choose to change your research focus to an emerging research area.You need a crash course in nanotechnology, to assess your current resources and future needs. With your particular need in mind, we persuaded SPIE Press to publish our short and readable introduction to nanotechnology. WhileNanotechnology: A Crash Course is unlikely to convert you overnight into a nanostar, it would meet your immediate need and very likely help you steer your professional life in a new direction.