Emerging Nanoelectronics
Life with and after CMOS
(Sprache: Englisch)
Emerging Nanoelectronics: Life with and after CMOS contains material and envisioned evolutions concerning limits forseen for CMOS technology, single electron devices and circuits, hybrid CMOS-SET circuit architecture and other novel devices and circuits...
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Emerging Nanoelectronics: Life with and after CMOS contains material and envisioned evolutions concerning limits forseen for CMOS technology, single electron devices and circuits, hybrid CMOS-SET circuit architecture and other novel devices and circuits operating with a few electrons. An engineering, practical point of view is systematically followed.Topics include:Volume 1 Fundamental CMOS Scaling Limits - Bio-NanotechnologyVolume 2 Few Electron Devices - Millipede Nanotechnology for Data StorageVolume 3 Nano-Scale Circuits and Architectures - NanophotonicsEmerging Nanoelectronics: Life with and after CMOS is written for students, researchers and professionals of engineering and science, practicing engineers, physicists and venture capitalists.
Emerging Nanoelectronics: Life with and after CMOS contains material and envisioned evolutions concerning limits forseen for CMOS technology, single electron devices and circuits, hybrid CMOS-SET circuit architecture and other novel devices and circuits operating with a few electrons. An engineering, practical point of view is systematically followed.
Topics include:
Volume 1 * Fundamental CMOS Scaling Limits - Bio-Nanotechnology
Volume 2 * Few Electron Devices - Millipede Nanotechnology for Data Storage
Volume 3 * Nano-Scale Circuits and Architectures - Nanophotonics
Emerging Nanoelectronics: Life with and after CMOS is written for students, researchers and professionals of engineering and science, practicing engineers, physicists and venture capitalists.
"This book will give you a wonderful overview and state of the art of the many possible options, which exist to extend microelectronics into nanoelectronics... I firmly believe that even though standard planar CMOS will eventually hit the wall, we will find solutions to take us another 30 years down the road, and lead to equally impressive achievements. This is an exciting time with many promising alternative solutions. Many new ideas and even a few old ones are being put on the table, researched, contemplated and prototyped. In the following pages you can read about these new developments in nanoelectronics..." Christopher Wasshuber, Texas Instruments
"....very well organized to provide insights in a seamless transition, from yesterday's micro-electronics, to tomorrow's nano-electronics--invaluable for graduate students and professionals." ..........Shekhar Borkar, Intel Fellow
''The editors have pulled together an exceptional collection of papers that provides a broad perspective on where electronics technology is, what the issues are, and that identifies the promise that exists.'' ........Professor Mark Lundstrom, Purdue University
''A timely and useful compendium of reference papers on nanoelectronics.'' ........Chenming Hu, CTO, TSMC
"A timely collection of seminal papers in the nanoelectronics area." ........H.-S. Philip Wong, IBM T.J. Watson Research Center
Topics include:
Volume 1 * Fundamental CMOS Scaling Limits - Bio-Nanotechnology
Volume 2 * Few Electron Devices - Millipede Nanotechnology for Data Storage
Volume 3 * Nano-Scale Circuits and Architectures - Nanophotonics
Emerging Nanoelectronics: Life with and after CMOS is written for students, researchers and professionals of engineering and science, practicing engineers, physicists and venture capitalists.
"This book will give you a wonderful overview and state of the art of the many possible options, which exist to extend microelectronics into nanoelectronics... I firmly believe that even though standard planar CMOS will eventually hit the wall, we will find solutions to take us another 30 years down the road, and lead to equally impressive achievements. This is an exciting time with many promising alternative solutions. Many new ideas and even a few old ones are being put on the table, researched, contemplated and prototyped. In the following pages you can read about these new developments in nanoelectronics..." Christopher Wasshuber, Texas Instruments
"....very well organized to provide insights in a seamless transition, from yesterday's micro-electronics, to tomorrow's nano-electronics--invaluable for graduate students and professionals." ..........Shekhar Borkar, Intel Fellow
''The editors have pulled together an exceptional collection of papers that provides a broad perspective on where electronics technology is, what the issues are, and that identifies the promise that exists.'' ........Professor Mark Lundstrom, Purdue University
''A timely and useful compendium of reference papers on nanoelectronics.'' ........Chenming Hu, CTO, TSMC
"A timely collection of seminal papers in the nanoelectronics area." ........H.-S. Philip Wong, IBM T.J. Watson Research Center
Inhaltsverzeichnis zu „Emerging Nanoelectronics “
- Invitation to Enter the NANO-World- Fundamental CMOS Scaling Limits: The 10 nm Wall?
- CMOS Scaling Challenges
- Lithography, Materials and Process Limits
- Nanometer Scale Challenges
- Interconnect Bottleneck: Issues and Alternatives
- Power Dissipation and Thermal Management
- Process Variations: A Key Issue
- Emerging Device Architectures: Evolutionary CMOS Device Technologies
- MOSFET Advanced Architectures: Metal versus Polysilicon Gate and High-K versus SiO2 Gate Dielectrics
- SIlicon-on-Insulator (SOI) CMOS: Mainstream or Niche Technology?
- Double-Gate, Multi-Gate and Fin-FETs: When the Gate Turns All-around
- Silicon-on-Nothing: the Disappearing Substrate or Building SOI on Bulk Silicon
- Vertical MOSFET: A Lithography Quasi-Independent Approach
- Strained Silicon MOSFET: Straining for Higher Mobility
- SiGe MOSFET: When Silicon and Germanium Become Good Allies
- Schottky MOSFET: The Metal-Semiconductor Contact at Nano-Scale
- Ballistic MOSFET: The End of the Mobility Concept
- Prospects for Sub-Ambient Temperature Operation: A Cool Technology?
- Prospects for New CMOS Logic Family
- Nanoscale System Design Challenges: Tyranny from the Tip
- Few Electron Devices
- Single Electron Devices and Coulomb Blockade
- Single Electron Transistor
- Simulation and Modeling
- C-SET or R-SET: Capacitative or Resistive Gate Dilemma versus Background Charge Sensitivity
- SET Fabrication Challenges: Ready for Room Temperature Operation?
- Ultimate Memory Architectures
- Single Electron Memory (SEM) for Terabit Storage
- SEM Architectures and Fabrication Techniques for Room Temperature Operation
- Single-Island Memory
- Nano-Grain Polycrystalline Film Silicon Memory
- Multiple-Island Nanocrystal Memories
- Silicon Nanowire SET Memories
- Key Emerging Memory Architectures
- OVONIC
- FeRAM
- MRAM
- Other Promising Memory Architectures for Nano-Scale Data
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Storage
- Hybrid CMOS-SET Memories
- NOVORAM
- IT Capacitor-less SOI Memory
- Millipede Nanotechnology for Data Storage
- Nano-Scale Circuits and Architectures: Replacement or Hybridization of CMOS Technology?
- Digital Computing with Few Electrons: To Mimic or not to Mimic CMOS?
- SET Inverter: Ultra-low Power Consumption versus Speed Limitation and Fan-Out Problems
- Other Single-Electron Logic Circuits: Digital Computing with a Few of Electrons
- Single Electronics for Analog and Sensing Applications
- SET-based Analog-to-Digital Converters
- RF-SET
- Single Electron Thermometer
- Electron Pump for Capacitance Standards
- Single Electron CCD: The Ultimately Small CCD Architecture?
- SET in Neural Networks
- Single-Electron Parametron and Quantum Cellular Automata (QCA): Computing with Quantum Dots
- Hybrid CMOS-SET Integrated Circuit Architectures: Illusion or Useful Compromise?
- Hybrid CMOS/SET Co-Simulation and Co-Design
- CMOS-SET IC Co-Fabrication: A Reality?
- Hybrid CMOS/RTD Nanoelectronic Circuits
- Nanowires for Future Dense Arrays Nanoelectronics
- Future Advanced CMOS/Nano Architectures
- Emerging Nanotechnologies: Life after CMOS?
- System Architectures for Nano-Scale Computing
- Molecular Electronics: The Computing Molecules
- Carbon Nanotubes: The Most Realistic Nano-Scale Emerging Technology?
- Spintronics: The Next Nobel-Prize-Winning Switch?
- Nanophotonics: Hacking Photonic Crystals
- Bio-Nanotechnology: Is this the Future?
- Conclusion
- Author's Index
- Subject Index
- Hybrid CMOS-SET Memories
- NOVORAM
- IT Capacitor-less SOI Memory
- Millipede Nanotechnology for Data Storage
- Nano-Scale Circuits and Architectures: Replacement or Hybridization of CMOS Technology?
- Digital Computing with Few Electrons: To Mimic or not to Mimic CMOS?
- SET Inverter: Ultra-low Power Consumption versus Speed Limitation and Fan-Out Problems
- Other Single-Electron Logic Circuits: Digital Computing with a Few of Electrons
- Single Electronics for Analog and Sensing Applications
- SET-based Analog-to-Digital Converters
- RF-SET
- Single Electron Thermometer
- Electron Pump for Capacitance Standards
- Single Electron CCD: The Ultimately Small CCD Architecture?
- SET in Neural Networks
- Single-Electron Parametron and Quantum Cellular Automata (QCA): Computing with Quantum Dots
- Hybrid CMOS-SET Integrated Circuit Architectures: Illusion or Useful Compromise?
- Hybrid CMOS/SET Co-Simulation and Co-Design
- CMOS-SET IC Co-Fabrication: A Reality?
- Hybrid CMOS/RTD Nanoelectronic Circuits
- Nanowires for Future Dense Arrays Nanoelectronics
- Future Advanced CMOS/Nano Architectures
- Emerging Nanotechnologies: Life after CMOS?
- System Architectures for Nano-Scale Computing
- Molecular Electronics: The Computing Molecules
- Carbon Nanotubes: The Most Realistic Nano-Scale Emerging Technology?
- Spintronics: The Next Nobel-Prize-Winning Switch?
- Nanophotonics: Hacking Photonic Crystals
- Bio-Nanotechnology: Is this the Future?
- Conclusion
- Author's Index
- Subject Index
... weniger
Autoren-Porträt von Adrian M. Ionescu, K. Banerjee
Adrian M. Ionescu is an Assistant Professor at the Swiss Federal Institute of Technology, Lausanne (EPFL), Switzerland. He received the PhD degree in Microelectronics from the University 'Politehnica' Bucharest, Romania, in 1994, and in Physics of Semiconductors from the Institut National Polytechnique de Grenoble, France, in 1997. He has held research scientist positions at LETI-CEA and LPCS-CNRS, Grenoble, France and he was a visiting researcher at the Center of Integrated Systems, Stanford University, USA. His research interests focus on micro- and nano-electronic devices aimed at Integrated Circuit design - especially process development, modelling and electrical characterization. Dr. Ionescu has authored more than 70 articles in international journals and conferences. He received three Best Paper Awards in international conferences and the Annual Award of the Technical Section of the Romanian Academy (of Sciences) in 1994. He is an expert for the IST program of the European Commission in Brussels since 1999. He is also director of the Institute of Microelectronics and Microsystems of EPFL since 2002.Kaustav Banerjee is an Assistant Professor in the Department of Electrical and Computer Engineering at the University of California, Santa Barbara. He received the Ph.D. degree in electrical engineering and computer sciences from the University of California at Berkeley in 1999. Prior to joining UCSB, he was with Stanford University, Stanford, CA, from 1999 to 2002 as a Research Associate at the Center for Integrated Systems. From February 2002 to August 2002 he was a Visiting Professor at the Circuit Research Labs of Intel in Hillsboro, Oregon. He has also held summer and/or visiting positions at Texas Instruments Inc., Dallas, Texas (1993-97), and Swiss Federal Institute of Technology (EPFL), Lausanne, Switzerland (2001), and has consulted for several EDA companies in the Silicon Valley. His research interests include nanometer scale circuit effects and their
... mehr
implications for high-performance and low-power VLSI and mixed-signal designs including their design automation methods. He has published over 70 research papers in archival journals and refereed international conferences on these subjects. He is the recipient of a Best Paper Award at the 2001 Design Automation Conference. Dr. Banerjee served as Technical Program Chair of the 2002 IEEE International Symposium on Quality Electronic Design (ISQED '02), and is the Conference Vice-Chair of ISQED '03. At present, he serves on the technical program committees of the EOS/ESD Symposium, and the IEEE International Reliability Physics Symposium (IRPS). He is a Senior Member of the IEEE.
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Bibliographische Angaben
- Autoren: Adrian M. Ionescu , K. Banerjee
- 2005, XXIV, 600 Seiten, Gebunden, Englisch
- Verlag: Springer Netherlands
- ISBN-10: 1402079176
- ISBN-13: 9781402079177
Sprache:
Englisch
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