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“Nanowire Field Effect Transistor: Basic Principles and Applications” places an emphasis on the application aspects of nanowire field effect transistors (NWFET). Device physics and electronics are discussed in a compact manner, together with the p-n junction diode and MOSFET, the former as an essential element in NWFET and the latter as a general background of the FET. During this discussion, the photo-diode, solar cell, LED, LD, DRAM, flash EEPROM and sensors are highlighted to pave the way for similar applications of NWFET. Modeling is discussed in close analogy and comparison with MOSFETs. Contributors focus on processing, electrostatic discharge (ESD) and application of NWFET. This includes coverage of solar and memory cells, biological and chemical sensors, displays and atomic scale light emitting diodes. Appropriate for scientists and engineers interested in acquiring a working knowledge of NWFET as well as graduate students specializing in this subject.
FinFET/GAA Modeling for IC Simulation and Design: Using the BSIM-CMG Standard, Second Edition is the first to book to explain FinFET modeling for IC simulation and the industry standard – BSIM-CMG - describing the rush in demand for advancing the technology from planar to 3D architecture as now enabled by the approved industry standard. The book gives a strong foundation on the physics and operation of FinFET, details aspects of the BSIM-CMG model such as surface potential, charge and current calculations, and includes a dedicated chapter on parameter extraction procedures, thus providing a step-by-step approach for the efficient extraction of model parameters. With this book, users will learn Why you should use FinFET, The physics and operation of FinFET Details of the FinFET standard model (BSIM-CMG), Parameter extraction in BSIM-CMG FinFET circuit design and simulation, and more. Authored by the lead inventor and developer of FinFET and developers of the BSIM-CMG standard model, providing an expert’s insight into the specifications of the standard A new edition of the original groundbreaking book on the industry-standard FinFET model—BSIM-CMG New to This Edition Includes a new chapter providing a comprehensive introduction to GAAFET, including motivations, device concepts, structure, benefits, and the industry standard GAAFET model Covers the most recent developments in the BSIM-CMG model Presents an updated RF modeling of FinFET using the BSIM-CMG model including parameter extraction Includes a new chapter on cryogenic modeling
The incessant scaling of complementary metal-oxide semiconductor (CMOS) technology has resulted in significant performance improvements in very-large-scale integration (VLSI) design techniques and system architectures. This trend is expected to continue in the future, but this requires breakthroughs in the design of nano-CMOS and post-CMOS technologies. Nanoelectronics refers to the possible future technologies beyond conventional CMOS scaling limits. This volume addresses the current state-of-the-art nanoelectronic technologies and presents potential options for next-generation integrated circuits. Nanoelectronics for Next-generation Integrated Circuits is a useful reference guide for researchers, engineers, and advanced students working on the frontier of the design and modeling of nanoelectronic devices and their integration aspects with future CMOS circuits. This comprehensive volume eloquently presents the design methodologies for spintronics memories, quantum-dot cellular automata, and post-CMOS FETs, including applications in emerging integrated circuit technologies.
Abstract Silicon planar MOSFETs are approaching their scaling limits. New device designs are being explored to replace the existing planar technology. Among the possible new device designs are Double Gate (DG) FETs, FinFETs, Tri-Gate FETs and Omega- Gate FETs. The Silicon Nanowire Gate All Around (GAA) FET stands out as one of the most promising FET designs due to its maximum gate effect in controlling the short channel effects. Recent developments such as synthesis of highly ordered nanowires and fabrication of nanowires as small as 1nm in diameter have illustrated the progress possible in silicon nanowire technology In this study we have explored the silicon nanowire FET as a possible candidate to replace the currently planar MOSFETs. In this thesis we investigated the silicon nanowire FET device and compared its performance with that of a double gate (DG) FET. The software used for the study assumed quantum-ballistic transport (NanoWire), which was developed at Purdue University. Initially, we presented a comparison of Nanowire FET with DG FET with for devices with same physical parameters. It was seen that superior subthreshold characteristics are exhibited by a silicon nanowire FET. We also conducted an optimization study for the 25 nm node from the ITRS report. The final device was optimized for both High Performance and Low Operating Power applications. A further study on future technology nodes down to the 14 nm node was performed which revealed short channel effects becomes significant at gate lengths ~ 5 nm even for a silicon nanowire device. Finally, a process variation study was conducted in comparison with a FinFET device. It was concluded that a silicon nanowire FET shows less sensitivity to process variation except it has higher sensitivity in variation with the diameter at less than ~4 nm than for FinFET where significant quantum effects set in. Variation with the gate length was found to be much less sensitive for the silicon nanowire FET because of its superior gate control characteristics.
A self-contained and up-to-date account of the current developments in the physics and technology of nanowire semiconductor devices.
In the last few years, the leading semiconductor industries have introduced multi-gate non-planar transistors into their core business. These are being applied in memories and in logical integrated circuits to achieve better integration on the chip, increased performance, and reduced energy consumption. Intense research is underway to develop these devices further and to address their limitations, in order to continue transistor scaling while further improving performance. This Special Issue looks at recent developments in the field of nanowire field-effect transistors (NW-FETs), covering different aspects of the technology, physics, and modelling of these nanoscale devices.
Advanced Field-Effect Transistors: Theory and Applications offers a fresh perspective on the design and analysis of advanced field-effect transistor (FET) devices and their applications. The text emphasizes both fundamental and new paradigms that are essential for upcoming advancement in the field of transistors beyond complementary metal–oxide–semiconductors (CMOS). This book uses lucid, intuitive language to gradually increase the comprehension of readers about the key concepts of FETs, including their theory and applications. In order to improve readers’ learning opportunities, Advanced Field-Effect Transistors: Theory and Applications presents a wide range of crucial topics: Design and challenges in tunneling FETs Various modeling approaches for FETs Study of organic thin-film transistors Biosensing applications of FETs Implementation of memory and logic gates with FETs The advent of low-power semiconductor devices and related implications for upcoming technology nodes provide valuable insight into low-power devices and their applicability in wireless, biosensing, and circuit aspects. As a result, researchers are constantly looking for new semiconductor devices to meet consumer demand. This book gives more details about all aspects of the low-power technology, including ongoing and prospective circumstances with fundamentals of FET devices as well as sophisticated low-power applications.
This book provides an overview of emerging semiconductor devices and their applications in electronic circuits, which form the foundation of electronic devices. Device Circuit Co-Design Issues in FETs provides readers with a better understanding of the ever-growing field of low-power electronic devices and their applications in the wireless, biosensing, and circuit domains. The book brings researchers and engineers from various disciplines of the VLSI domain together to tackle the emerging challenges in the field of engineering and applications of advanced low-power devices in an effort to improve the performance of these technologies. The chapters examine the challenges and scope of FinFET device circuits, 3D FETs, and advanced FET for circuit applications. The book also discusses low-power memory design, neuromorphic computing, and issues related to thermal reliability. The authors provide a good understanding of device physics and circuits, and discuss transistors based on the new channel/dielectric materials and device architectures to achieve low-power dissipation and ultra-high switching speeds to fulfill the requirements of the semiconductor industry. This book is intended for students, researchers, and professionals in the field of semiconductor devices and nanodevices, as well as those working on device-circuit co-design issues.
Nanowires are attracting wide scientific interest due to the unique properties associated with their one-dimensional geometry. Developments in the understanding of the fundamental principles of the nanowire growth mechanisms and mastering functionalization provide tools to control crystal structure, morphology, and the interactions at the material interface, and create characteristics that are superior to those of planar geometries. This book provides a comprehensive overview of the most important developments in the field of nanowires, starting from their synthesis, discussing properties, and finalizing with nanowire applications. The book consists of two parts: the first is devoted to the synthesis of nanowires and characterization, and the second investigates the properties of nanowires and their applications in future devices.