المصدر: كتب فى مجال Nanostructure and Quantum Dots في منتدى : النانوتكنولوجي و المواد النانوية Language: english Paperback: 554 pages Data: February 17, 2003 Format: PDF Description: Jasprit Singh presents the underlying physics behind devices that drive today's technologies, utilizing carefully chosen solved examples to convey important concepts. Real-world applications are highlighted throughout the book, stressing the links between physical principles and actual devices. The volume provides engineering and physics students and professionals with complete coverage of key modern semiconductor concepts. Lateral Alignment of Epitaxial Quantum Dots | Pages: 708 | 2007-09-14 || PDF | 19 MB Accurate positioning of self-organized nanostructures on a substrate surface can be regarded as the Achilles heel of nanotechnology. This perception also applies to self-assembled semiconductor quantum dots. This book describes the full range of possible strategies to laterally align self-assembled quantum dots on a substrate surface, starting from pure self-ordering mechanisms and culminating with forced alignment by lithographic positioning. The text addresses both short- and long-range ordering phenomena and paves the way for the future high integration of single quantum dot devices on a single chip. Contributions by the best-known experts in this field ensure that all relevant quantum-dot heterostructures are elucidated from diverse relevant perspectives. Self-Assembled Quantum Dots Series: , Vol. 1 2008, XII, 468 p. 250 illus., Hardcover Product Description In recent years, the field of self-assembled quantum dots has shown great promise for nanoscale applications in optoelectronics and quantum computing. Worldwide efforts in both theory and experimental investigations have driven the growth, characterization, and applications of quantum dots into an advanced multidisciplinary field. Written by leading experts in the field,Self-Assembled Quantum Dotsprovides up-to-date coverage of carrier and spin dynamics and energy transfer and structural interaction among nanostructures. Topics also includes current device applications such as quantum dot lasers and detectors as well as future applications to quantum information processing. Semiconductor Device Physics and Design 2008, XXIV, 560 p., Hardcover description Device dimensions and geometrics are now such that one cannot solve device problems analytically Simulators do not allow students to see the physics of the problem and how intelligent choices on doping, geometry and heterostructures will impact devices Carefully discusses and presents analytical models and then provides simulation based advanced results Teaches the student/engineer how to approach device design from the point of view of someone who wants to improve devices and can see the opportunity and challenges Includes end of chapter problems that have been carefully chosen to test students' knowledge by solving real-life problems Semiconductor Device Physics and Design provides a fresh and unique teaching tool. Over the last decade device performances are driven by new materials, scaling, heterostructures and new device concepts. Semiconductor devices have mostly relied on Si but increasingly GaAs, InGaAs and heterostructures made from Si/SiGe, GaAs/AlGaAs etc have become important. Over the last few years one of the most exciting new entries has been the nitride based heterostructures. New physics based on polar charges and polar interfaces has become important as a result of the nitrides. Nitride based devices are now used for high power applications and in lighting and display applications. For students to be able to participate in this exciting arena, a lot of physics, device concepts, heterostructure concepts and materials properties need to be understood. It is important to have a textbook that teaches students and practicing engineers about all these areas in a coherent manner. Semiconductor Device Physics and Design starts out with basic physics concepts including the physics behind polar heterostructures and strained heterostructures. Important devices ranging from p-n diodes to bipolar and field effect devices are then discussed. An important distinction users will find in this book is the discussion presented on device needs from the perspective of various technologies. For example, how much gain is needed in a transistor, how much power, what kind of device characteristics is needed? Not surprisingly the needs depend upon applications. The needs of an A/D or D/A converter will be different from that of an amplifier in a cell phone. Similarly the diodes used in a laptop will place different requirements on the device engineer than diodes used in a mixer circuit. By relating device design to device performance and then relating device needs to system use the student can see how device design works in real world. Semiconductor Device Physics and Design is comprehensive without being overwhelming. The focus was to make this a useful text book so that the information contained is cohesive without including all aspects of device physics. The lesson plans demonstrated how this book could be used in a 1 semester or 2 quarter sequence. Semiconductor Nanostructures for Optoelectronic Applications Title of ebook: Semiconductor Nanostructures for Optoelectronic Applications Internet download file size: 12553 kb Published: 07-2004 Released online for download: 07-01-2004 description Written by today's best researchers of semiconductor nanostructures, this cutting-edge resource provides a snapshot of this exciting and fast-changing field. The book covers the latest advances in nanotechnology and discusses the applications of nanostructures to optoelectronics, photonics, and electronics. You learn how to grow, characterize and design optoelectronic devices using semiconductor nanostrucutres, and how to incorporate semiconductor nanostructures materials into conventional quantum well devices. Moreover, the book reviews optical, electronic, and structural characterization techniques to help you determine the properties of nanostructures and explore novel nanostructured materials. This unique reference describes revolutionary devices that have been enabled by the growth of quantum dots, including quantum dot lasers and quantum dot detectors. You find detailed discussions on some of the more promising semiconductor material systems that have demonstrated nanostructuring, such as III-Nitrides, antimony-based, Silicon germanium, and Zinc Oxide. The book also provides a solid understanding of ordered carbon nanotubes and related structures, along with explanations of their novel uses as infrared detectors and solar cells. .reviewsseries{ font-family:arial,helvetica; font-size:12px; line-height:16px; border:1px solid #dfdfdf; background-color: #efefef; clear:both; width:600px; padding:7px; margin-left:0px; margin-top:0; margin-bottom:15px; float:left; } .scrollbox { position: relative; width: 560px; height: 186px; overflow: hidden; float: left;} .scrollprevious, .scrollnext { width: 18px; height: 167px; text-align: center; vertical-align: middle; float: left; margin: 0 4px 0 0; color: white; font-weight: bold; display: block; cursor: pointer; outline: none; } .scrollnext { margin: 0 0 0 0; } .scrollnext a{ background: url("/mas_assets/scroll_right_hover.gif") 0 0 no-repeat; height:186px; width:18px; display:block; } .scrollnext a:hover { background-position: -18px 0; } .scrollprevious a{ background: url("/mas_assets/scroll_left_hover.gif") 0 0 no-repeat; height:186px; width:18px; display:block; } .scrollprevious a:hover { background-position: -18px 0; } .scrollthumb { float: left; height: 280px; padding: 10px; width: 180px; } .scrollthumb h4 { margin: 10px 0; font-size: 12px; color: tomato; } .scrollthumb p { margin: 10px 0; font-size: 10px; } .box { background-color:#f5f5f5; border:0px solid #cfcfcf; display:block; float:left; height:184px !important; margin:0 2px 10px 1px !important; width:108px !important; padding: 0 !important; } .box a{ font-size:10px; font-family:verdana,sans-serif; } .box p{ margin:0 0 7px 0; clear:both; } .box td{ text-align:center; padding:0; } .box .thumb{ border:1px solid #c1c1c1; margin:0px; padding:0; } .box table { margin: 2px !important; } Semiconductor Nanostructures Series: 2008, XXII, 358 p. 245 illus., 17 in color., Hardcover About this book A field highly relevant to novel technologies Written by recognized leaders from research Hot topic in device laboratories around the world Reducing the size of a coherently grown semiconductor cluster in all three directions of space to a value below the de Broglie wavelength of a charge carrier leads to complete quantization of the energy levels, density of states, etc. Such "quantum dots" are more similar to giant atoms in a dielectric cage than to classical solids or semiconductors showing a dispersion of energy as a function of wavevector. Their electronic and optical properties depend strongly on their size and shape, i.e. on their geometry. By designing the geometry by controlling the growth of QDs, absolutely novel possibilities for material design leading to novel devices are opened. This multiauthor book written by world-wide recognized leaders of their particular fields and edited by the recipient of the Max-Born Award and Medal 2006 Professor Dieter Bimberg reports on the state of the art of the growing of quantum dots, the theory of self-organised growth, the theory of electronic and excitonic states, optical properties and transport in a variety of materials. It covers the subject from the early work beginning of the 1990s up to 2006. The topics addressed in the book are the focus of research in all leading semiconductor and optoelectronic device laboratories of the world. Quantum Dots: A Survey of the Properties of Artificial Atoms (Hardcover) Product details Hardcover: 348 pages Language English Product Description This book deals with the electronic and optical properties of two low-dimensional systems of quantum dots and quantum antidots. It is divided into two parts. Part one is a self-contained monograph which describes in detail the theoretical and experimental background for exploration of electronic states of the quantum-confined systems. Starting from the single-electron picture of the system, the book describes various experimental methods that provide important information on these systems. Concentrating on many-electron systems, theoretical developments are described in detail and their experimental consequences are also discussed. The field has witnessed an almost explosive growth and some of the future directions of explorations are highlighted towards the end of the monograph. The subject matter is dealt with in such a way that it is both accessible to beginners and useful for expert researchers as a comprehensive review of most of the developments in the field. Furthermore the book contains 37 reprinted articles which have been selected to provide a first-hand picture of the overall developments in the field. The early papers have been arranged to portray the developments chronologically, and the more recent papers provide an overview of future direction in the research. All in
