Future Trends in Microelectronics: From Nanophotonics to Sensors and Energy
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More About This Title Future Trends in Microelectronics: From Nanophotonics to Sensors and Energy

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In the summer of 2009, leading professionals from industry, government, and academia gathered for a free-spirited debate on the future trends of microelectronics. This volume represents the summary of their valuable contributions. Providing a cohesive exploration and holistic vision of semiconductor microelectronics, this text answers such questions as: What is the future beyond shrinking silicon devices and the field-effect transistor principle? Are there green pastures beyond the traditional semiconductor technologies? This resource also identifies the direction the field is taking, enabling microelectronics professionals and students to conduct research in an informed, profitable, and forward-looking fashion.

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Dr. Serge Luryi is a Distinguished Professor and Chair of Electrical and Computer Engineering at the State University of New York at Stony Brook. Since 1998, Dr. Luryi has been Director of the New York State Center for Advanced Technology in Sensor Systems. He has published over 200 papers and has been awarded forty-seven U.S. patents.

Dr. Jimmy Xu is the Charles C. Tillinghast Jr. '32 University Professor and Professor of Engineering and Physics at Brown University. Previously, he was the Nortel Chair in Emerging Technologies and James Ham Chair in Optoelectronics, as well as director of Nortel Institute for Telecommunications at the University of Toronto.

Dr. Alex Zaslavsky is Professor of Engineering and Physics at Brown University. He has published over eighty journal articles and book chapters, and coedited six books in the microelectronics field. Since 2003, he has been an editor of Solid-State Electronics: An International Journal.

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Preface (S. Luryi, J. M. Xu, and A. Zaslavsky).

1 OPTOELECTRONICS AND NANOPHOTONICS.

Nanophotonics for Information Systems (Y. Fainman).

What Will Modern Photonics Contribute to the Development of Future Optical Communication Technology? (Djafar K. Mynbaev).

Ultrafast Nanophotonic Devices For Optical Interconnects (N. N. Ledentsov).

Intersubband Quantum-Box Lasers: Progress and Potential as Uncooled Mid-Infrared Sources (D. Botez, G. Tsvid, M. D'Souza, J. C. Shin, Z. Liu, J. H. Park, J. Kirch, L. J. Mawst, M. Rathi, T. F. Kuech, I. Vurgaftman, J. Meyer, J. Plant, G. Turner, and P. Zory).

GaSb-based Type-I Laser Diodes Operating at 3 µm and Beyond (L. Shterengas, G. Kipshidze, T. Hosoda, and G. Belenky).

Bridging Optics and Electronics with Quantum Cascade Lasers, Antennas, and Circuits (J. Faist, C. Walther, M. Amanti, G. Scalari, M. Fischer, and M. Beck).

Towards Intersubband Polaritonics: How Fast Can Light and Electrons Mate? (A. A. Anappara, L. Sorba, A. Tredicucci, G. Günter, A. Sell,A. Leitenstorfer, R. Huber, S. De Liberato, C. Ciuti, and G. Biasiol).

Si3N4/SiO2 Planar Photonic Structures Fabricated by Focused Ion Beam (L. A. M. Barea, F. Vallini, D. L. S. Figueira, A. Da Silva Filho, N. C. Frateschi, and A. R. Vaz).

2 ELECTRONIC DEVICES AND SYSTEMS.

Silicon-Based Devices and Materials for Nanoscale CMOS and Beyond-CMOS (F. Balestra).

Device Proposals Beyond Silicon CMOS (P. M. Solomon).

GeOI as a Platform for Ultimate Devices (W. Van Den Daele, S. Cristoloveanu, E. Augendre, C. Le Royer, J.-F. Damlencourt, D. Kazazis, and A. Zaslavsky).

Simulation of Self-Heating Effects in Different SOI MOS Architectures (Enrico Sangiorgi, Marco Braccioli and Claudio Fiegna).

Nanowires: Technology, Physics and Perspectives (D. Grützmacher, Th. Schäpers, S. Mantl, S. Feste, Q. T. Zhao, H. Hardtdegen, R. Calarco, M. Lepsa, and N. Demarina).

Emerging Nanotechnology for Integration of Nanostructures in Nanoelectronic Devices (T. Baron, C. Agraffeil, F. Dhalluin, M. Kogelschtaz, G. Cunge, T. Chevolleau, B. Salem, B. Salhi, H. Abed, A. Potié, L. Latu-Romain, C. Ternon, K. Aissou, L. Montès, Mur, G. Molas, B. De Salvo, E. Jalaguier, T. Ernst, P. Ferret, P. Gentile, and N. Pauc).

Scrolled Si/SiGe Heterostructures as Building Blocks for Tube-Like Field-Effect Transistors (N. V. Demarina and D. Grützmacher).

Silicon Nanowire-Based Nonvolatile Memory Cells: Progress and Prospects (Qiliang Li, X. Zhu, Y. Yang, D. E. Ioannou, J. S. Suehle, and C. A. Richter).

Prospects and Challenges of Next-Generation Flash Memory Devices (Jang-Sik Lee).

Chalcogenide Glassy Semiconductors - Could They Replace Silicon in Memory Devices? (K. D. Tsendin).

Current Status and Recent Developments in RSFQ Processor Design (M. Dorojevets).

1/f Noise: The Funeral is Cancelled (or Postponed) (M. E. Levinshtein and S. L. Rumyantsev).

3 PHYSICS, BIOLOGY, AND OTHER SISTER SCIENCES.

Spin Hall Effect (M. I. Dyakonov).

Can Biology Provide Creative Solutions for Next-Generation Memory Devices? (W. E. van den Berg and S. A. Kushner).

Spin Screening of Magnetization Due to Inverse Proximity Effect in Superconducting/Ferromagnetic Bilayers (V. Shelukhin, M. Karpovski, A. Palevski, J. Xia, A. Kapitulnik, and A. Tsukernik).

Silicon for Spintronic Applications: Strain-Enhanced Valley Splitting (V. Sverdlov, O. Baumgartner, T. Windbacher, and S. Selberherr).

Graphene-Based Terahertz Devices: Concepts and Characteristics (V. Ryzhii, M. Ryzhii, A. Satou, N. Ryabova, T. Otsuji, V. Mitin, F. T. Vasko, A. A. Dubinov, V. Y. Aleshkin, and M. S. Shur).

Directed Self-Assembly - A Controllable Route to Optical and Electronic Devices Based on Single Nanostructures (R. L. Williams, D. Dalacu, M. E. Reimer, K. Mnaymneh, V. Sazonova, P. J. Poole, G. C. Aers, R. Cheriton, S. Frédérick, D. Kim, J. Lapointe, P. Hawrylak, and M. Korkusiński).

4 SENSORS, DETECTORS, AND ENERGY.

Three-Dimensional Position-Sensitive Wide Bandgap Semiconductor Gamma-Ray Imaging Detectors (Zhong He).

Semiconductor Scintillator for Three-Dimensional Array of Radiation Detectors (Serge Luryi and Arsen Subashiev).

Semiconductor Gamma Radiation Detectors: Band Structure Effects in Energy Resolution (Arsen Subashiev and Serge Luryi).

The Future of Microelectronics is … Macroelectronics (M. A. Alam, N. Pimparkar, and B. Ray).

An Integration Challenge: Information and Communication Technologies to Address Indoor Air Quality in Commercial Buildings (M. D'Iorio).

Quantum-Dot Infrared Photodetectors: In Search of the Right Design for Room-Temperature Operation (A. Sergeev, V. Mitin, L. H. Chien, and N. Vagidov).

Treating the Case of Incurable Hysteresis in VO2 (M. Gurvitch, S. Luryi, A. Polyakov, and A. Shabalov).

Exploratory Studies on Silicon-Based Oxide Fuel Cell Power Sources Incorporating Ultrathin Nanostructured Platinum and Cerium Oxide Films as Anode Components (Bo-Kuai Lai, A. C. Johnson, H. Xiong, C. Ko, and S. Ramanathan).

Index.

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"This volume represents the summary of their valuable contributions. Providing a cohesive exploration and holistic vision of semiconductor microelectronics, this text answers such questions as: What is the future beyond shrinking silicon devices and the field-effect transistor principle? Are there green pastures beyond the traditional semiconductor technologies?." (Nanotechnology Now, 2 November 2010)

"This volume represents the summary of their valuable contributions . . . providing a cohesive exploration and holistic vision of semiconductor microelectronics". (Wireless Design & Development, 4 November 2010)

"This volume represents the summary of their valuable contributions. Providing a cohesive exploration and holistic vision of semiconductor microelectronics, this text answers such questions as: What is the future beyond shrinking silicon devices and the field-effect transistor principle? Are there green pastures beyond the traditional semiconductor ? This resource also identifies the direction the field is taking, enabling microelectronics professionals and students to conduct research in an informed, profitable, and forwardlooking fashion." (Digital Producer Magazine, 2 November 2010)

 

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