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Opening with a brief historical account of electron transport from Ohm's law through transport in semiconductor nanostructures, this book discusses topics related to electronic quantum transport. The book is written for graduate students and researchers in the field of mesoscopic semiconductors or in semiconductor nanostructures. Highlights include review of the cryogenic scanning probe techniques applied to semiconductor nanostructures.
Mesoscopic physics deals with systems larger than single atoms but small enough to retain their quantum properties. The possibility to create and manipulate conductors of the nanometer scale has given birth to a set of phenomena that have revolutionized physics: quantum Hall effects, persistent currents, weak localization, Coulomb blockade, etc. This Special Issue tackles the latest developments in the field. Contributors discuss time-dependent transport, quantum pumping, nanoscale heat engines and motors, molecular junctions, electron–electron correlations in confined systems, quantum thermo-electrics and current fluctuations. The works included herein represent an up-to-date account of exciting research with a broad impact in both fundamental and applied topics.
This book reviews research on single-electron devices and circuits in silicon. These devices provide a means to control electronic charge at the one-electron level and are promising systems for the development of few-electron, nanoscale electronic circuits. The book considers the design, fabrication, and characterization of single-electron transistors, single-electron memories, few-electron transfer devices such as electron pumps and turnstiles, and single-electron logic devices. A review of the many different approaches used for the experimental realisation of these devices is provided and devices developed during the author''s own research are used as detailed examples. An introduction to the physics of single-electron charging effects is included. Sample Chapter(s). Chapter 1: Introduction (301 KB). Contents: Introduction; Single-Electron Charging Effects; Single-Electron Transistors in Silicon; Single-Electron Memory; Few-Electron Transfer Devices; Single-Electron Logic Circuits. Readership: Researchers, academics, and postgraduate students in nanoelectronics, nanofabrication, nanomaterials and nanostructures, quantum physics and electrical & electronic engineering.
Integrated Silicon-Metal Systems at the Nanoscale: Applications in Photonics, Quantum Computing, Networking, and Internet is a comprehensive guide to the interaction, materials and functional integration at the nanoscale of the silicon-metal binary system and a variety of emerging and next-generation advanced device applications, from energy and electronics, to sensing, quantum computing and quantum internet networks. The book guides the readers through advanced techniques and etching processes, combining underlying principles, materials science, design, and operation of metal-Si nanodevices. Each chapter focuses on a specific use of integrated metal-silicon nanostructures, including storage and resistive next-generation nano memory and transistors, photo and molecular sensing, harvest and storage device electrodes, phosphor light converters, and hydrogen fuel cells, as well as future application areas, such as spin transistors, quantum computing, hybrid quantum devices, and quantum engineering, networking, and internet. - Provides detailed coverage of materials, design and operation of metal-Si nanodevices - Offers a step-by-step approach, supported by principles, methods, illustrations and equations - Explores a range of cutting-edge emerging applications across electronics, sensing and quantum computing
Written by international experts, Physics and Applications of Semiconductor Quantum Structures covers the most important recent advances in the field. Beginning with a review of the evolution of semiconductor superlattices and quantum nanostructures, the book explores fabrication and characterization techniques, transport, optical, and spin-depende
Is Bigger Always Better? Explore the Behavior of Very Small Devices as Described by Quantum Mechanics Smaller is better when it comes to the semiconductor transistor. Nanoscale Silicon Devices examines the growth of semiconductor device miniaturization and related advances in material, device, circuit, and system design, and highlights the use of device scaling within the semiconductor industry. Device scaling, the practice of continuously scaling down the size of metal-oxide-semiconductor field-effect transistors (MOSFETs), has significantly improved the performance of small computers, mobile phones, and similar devices. The practice has resulted in smaller delay time and higher device density in a chip without an increase in power consumption. This book covers recent advancements and considers the future prospects of nanoscale silicon (Si) devices. It provides an introduction to new concepts (including variability in scaled MOSFETs, thermal effects, spintronics-based nonvolatile computing systems, spin-based qubits, magnetoelectric devices, NEMS devices, tunnel FETs, dopant engineering, and single-electron transfer), new materials (such as high-k dielectrics and germanium), and new device structures in three dimensions. It covers the fundamentals of such devices, describes the physics and modeling of these devices, and advocates further device scaling and minimization of energy consumption in future large-scale integrated circuits (VLSI). Additional coverage includes: Physics of nm scaled devices in terms of quantum mechanics Advanced 3D transistors: tri-gate structure and thermal effects Variability in scaled MOSFET Spintronics on Si platform NEMS devices for switching, memory, and sensor applications The concept of ballistic transport The present status of the transistor variability and more An indispensable resource, Nanoscale Silicon Devices serves device engineers and academic researchers (including graduate students) in the fields of electron devices, solid-state physics, and nanotechnology.
Technological advancement in chip development, primarily based on the downscaling of the feature size of transistors, is threatening to come to a standstill as we approach the limits of conventional scaling. For example, when the number of electrons in a device's active region is reduced to less than ten electrons (or holes), quantum fluctuation errors will occur, and when gate insulator thickness becomes too insignificant to block quantum mechanical tunneling, unacceptable leakage will occur. Fortunately, there is truth in the old adage that whenever a door closes, a window opens somewhere else. In this case, that window opening is nanotechnology. Silicon Nanoelectronics takes a look at at the recent development of novel devices and materials that hold great promise for the creation of still smaller and more powerful chips. Silicon nanodevices are positoned to be particularly relevant in consideration of the existing silicon process infrastructure already in place throughout the semiconductor industry and silicon's consequent compatibility with current CMOS circuits. This is reinforced by the nearly perfect interface that can exist between natural oxide and silicon. Presenting the contributions of more than 20 leading academic and corporate researchers from the United States and Japan, Silicon Nanoelectronics offers a comprehensive look at this emergent technology. The text includes extensive background information on the physics of silicon nanodevices and practical CMOS scaling. It considers such issues as quantum effects and ballistic transport and resonant tunneling in silicon nanotechnology. A significant amount of attention is given to the all-important silicon single electron transistors and the devices that utilize them. In offering an update of the current state-of-the-art in the field of silicon nanoelectronics, this volume serves well as a concise reference for students, scientists, engineers, and specialists in various fields, in
Here is a discussion of the state of the art of spin resonance in low dimensional structures, such as two-dimensional electron systems, quantum wires, and quantum dots. Leading scientists report on recent advances and discuss open issues and perspectives.
This detailed book addresses three main areas of solid state electronics, providing an insight into the state of the art in material and device research that will be of interest to all those involved in compound semiconductors.