Nano Cmos Gate Dielectric Engineering

According to Moore’s Law, not only does the number of transistors in an integrated circuit double every two years, but transistor size also decreases at a predictable rate. At the rate we are going, the downsizing of CMOS transistors will reach the deca-nanometer scale by 2020. Accordingly, the gate dielectric thickness will be shrunk to less than half-nanometer oxide equivalent thickness (EOT) to maintain proper operation of the transistors, leaving high-k materials as the only viable solution for such small-scale EOT. This comprehensive, up-to-date text covering the physics, materials, devices, and fabrication processes for high-k gate dielectric materials, Nano-CMOS Gate Dielectric Engineering systematically describes how the fundamental electronic structures and other material properties of the transition metals and rare earth metals affect the electrical properties of the dielectric films, the dielectric/silicon and the dielectric/metal gate interfaces, and the resulting device properties. Specific topics include the problems and solutions encountered with high-k material thermal stability, defect density, and poor initial interface with silicon substrate. The text also addresses the essence of thin film deposition, etching, and process integration of high-k materials in an actual CMOS process. Fascinating in both content and approach, Nano-CMOS Gate Dielectric Engineering explains all of the necessary physics in a highly readable manner and supplements this with numerous intuitive illustrations and tables. Covering almost every aspect of high-k gate dielectric engineering for nano-CMOS technology, this is a perfect reference book for graduate students needing a better understanding of developing technology as well as researchers and engineers needing to get ahead in microelectronic engineering and materials science.

According to Moore’s Law, not only does the number of transistors in an integrated circuit double every two years, but transistor size also decreases at a predictable rate. At the rate we are going, the downsizing of CMOS transistors will reach the deca-nanometer scale by 2020. Accordingly, the gate dielectric thickness will be shrunk to less than half-nanometer oxide equivalent thickness (EOT) to maintain proper operation of the transistors, leaving high-k materials as the only viable solution for such small-scale EOT. This comprehensive, up-to-date text covering the physics, materials, devices, and fabrication processes for high-k gate dielectric materials, Nano-CMOS Gate Dielectric Engineering systematically describes how the fundamental electronic structures and other material properties of the transition metals and rare earth metals affect the electrical properties of the dielectric films, the dielectric/silicon and the dielectric/metal gate interfaces, and the resulting device properties. Specific topics include the problems and solutions encountered with high-k material thermal stability, defect density, and poor initial interface with silicon substrate. The text also addresses the essence of thin film deposition, etching, and process integration of high-k materials in an actual CMOS process. Fascinating in both content and approach, Nano-CMOS Gate Dielectric Engineering explains all of the necessary physics in a highly readable manner and supplements this with numerous intuitive illustrations and tables. Covering almost every aspect of high-k gate dielectric engineering for nano-CMOS technology, this is a perfect reference book for graduate students needing a better understanding of developing technology as well as researchers and engineers needing to get ahead in microelectronic engineering and materials science.

Based on the authors' expansive collection of notes taken over the years, Nano-CMOS Circuit and Physical Design bridges the gap between physical and circuit design and fabrication processing, manufacturability, and yield. This innovative book covers: process technology, including sub-wavelength optical lithography; impact of process scaling on circuit and physical implementation and low power with leaky transistors; and DFM, yield, and the impact of physical implementation.

Over two volumes this work describes the modelling, design, and implementation of nano-scaled CMOS electronics, and the new generation of post-CMOS devices, at both the device and circuit levels.

A state-of-the-art overview of high-k dielectric materials for advanced field-effect transistors, from both a fundamental and a technological viewpoint, summarizing the latest research results and development solutions. As such, the book clearly discusses the advantages of these materials over conventional materials and also addresses the issues that accompany their integration into existing production technologies. Aimed at academia and industry alike, this monograph combines introductory parts for newcomers to the field as well as advanced sections with directly applicable solutions for experienced researchers and developers in materials science, physics and electrical engineering.

In this book, internationally recognized researchers give a state-of-the-art overview of the electronic device architectures required for the nano-CMOS era and beyond. Challenges relevant to the scaling of CMOS nanoelectronics are addressed through different core CMOS and memory device options in the first part of the book. The second part reviews new device concepts for nanoelectronics beyond CMOS. The book covers the fundamental limits of core CMOS, improving scaling by the introduction of new materials or processes, new architectures using SOI, multigates and multichannels, and quantum computing.

This book presents the material necessary for understanding the physics, operation, design, and performance of modern MOSFETs with nanometer dimensions. It offers a brief introduction to the field and a thorough overview of MOSFET physics, detailing the relevant basics. The authors apply presented models to calculate and demonstrate transistor characteristics, and they include required input data (e.g., dimensions, doping) enabling readers to repeat the calculations and compare their results. The book introduces conventional and novel advanced MOSFET concepts, such as multiple-gate structures or alternative channel materials. Other topics covered include high-k dielectrics and mobility enhancement techniques, MOSFETs for RF (radio frequency) applications, MOSFET fabrication technology.

This volume explores and addresses the challenges of high-k gate dielectric materials, one of the major concerns in the evolving semiconductor industry and the International Technology Roadmap for Semiconductors (ITRS). The application of high-k gate dielectric materials is a promising strategy that allows further miniaturization of microelectronic components. This book presents a broad review of SiO2 materials, including a brief historical note of Moore’s law, followed by reliability issues of the SiO2 based MOS transistor. It goes on to discuss the transition of gate dielectrics with an EOT ~ 1 nm and a selection of high-k materials. A review of the various deposition techniques of different high-k films is also discussed. High-k dielectrics theories (quantum tunneling effects and interface engineering theory) and applications of different novel MOSFET structures, like tunneling FET, are also covered in this book. The volume also looks at the important issues in the future of CMOS technology and presents an analysis of interface charge densities with the high-k material tantalum pentoxide. The issue of CMOS VLSI technology with the high-k gate dielectric materials is covered as is the advanced MOSFET structure, with its working structure and modeling. This timely volume will prove to be a valuable resource on both the fundamentals and the successful integration of high-k dielectric materials in future IC technology.