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Global Roadmap for Ceramic and Glass Technology
Stephen W. Freiman (Edited by), S Freiman (Author), Mrityunjay Singh (Edited by), Gary S. Fischman (Edited by), John Hellmann (Edited by), Kathryn Logan (Edited by), Tom Coyle (Edited by), Linn Hobbs (Edited by), Jeffrey D. Smith (Edited by), Costa Sideridis (Edited by), Marty Green (Edited by), Robert D. Cook (Edited by)
9780470104910, Wiley
Multiple-component retail product, part(s) enclosed, published 3 August 2007
968 pages
24.4 x 16.4 x 4.8 cm, 1.533 kg
This is the only global roadmap that identifies the technical and manufacturing challenges associated with the development and expansion of commercial markets for ceramics and glass. Featuring presentations by industry leaders at the 1st International Congress on Ceramics (ICC) held in 2006, it suggests positive, proactive ways to address these challenges. The ICC Global Roadmap contains the following content:
1) Summary papers prepared by the invited speakers before the meeting
2) A detailed account of the presentation of each invited speaker written by an editor who attends the presentation
3) A summary account and future recommendations for the industry on each topic covered written by the board and the president of this meeting, Dr. Stephen Freiman (National Institutes of Standards and Technology)
4) The CDRom accompanying the book contains all of the above as well as pdfs of the presentations for non-invited speakers, including posters presented and discussed.
Preface xiii A Global Roadmap for Ceramics 1 PART 1. INTERNATIONAL TRENDS AND BUSINESS PERSPECTIVES International Trends and Business Perspectives Overview 15 Ceramic Technology Development at Kyocera 19 Kyocera’s Vision for the Future 23 The New Global Business Model for Technology Companies 29 Research and Development of Fine Ceramics—Roadmaps in Japan and Strategies in NIMS 37 Programs and Progress of Advanced Ceramic Materials Research and Development in China 49 The UK’S Structural Ceramics Network 63 Industrial Ceramics—History, Trends, and Implications for the Future 67 Perspective from the Association of American Ceramic Components Manufacturers 77 Prospects for Ceramic Technology in United Technologies Corporation 81 PART 2. INNOVATION AND INVENTION Innovation and Invention Overview 85 Measurement Science and Technology for Ceramics Innovations 89 Opportunities for Ceramic Education in a Materials World 117 Ceramics at the National Science Foundation (NSF)—Trends and Opportunities 127 Patenting Ceramic-Related Inventions in the United States and Internationally in the Twenty-First Century 161 Innovative Technology from Promising to Practical—The Role of Standards 175 PART 3. BIOLOGY AND MEDICINE Ceramics in Biology and Medicine Overview 183 Challenges for Bioceramics in the 21st Century 189 Applications of Photonics and Ceramics to Health Care—The Future Has Begun 197 Laser-Assisted Rapid Prototyping of Dental Components in the SiO2–Al2O3 System 211 The Future of Glass–Ceramics as Biomaterials 225 Bio-Prosthesis—A New Concept Based on Hybrid Composites 231 Bioactive Glass Tissue Scaffolds and Their Three-Dimensional Characterization 249 PART 4. CONSUMER PRODUCTS Consumer Products Overview 263 Future for Ceramics for Consumer Products 267 Importance of the Ceramics Industry in Mexico 275 PART 5. ELECTRONICS Electronics Overview 289 Integration and Process Strategies for Ceramics in Advanced Microsystems 293 Nonvolatile Memory and Recent News of RFCPU on Glass Substrate 311 Trends in Research and Development on Microwave Materials for Low-Temperature Co-Fired Ceramics 325 Ceramic Technology and Nanotechnology Combine 353 Present and Future Challenges in Multilayer Ceramic Devices 361 Trends in Ferroelectric/Piezoelectric Ceramics 381 Ceramics in Packaging 397 Nanoparticle Engineering For Next-Generation Poly Isolation Chemical Mechanical Planarizaion in ULSI Process 419 PART 6. ENERGY Ceramics in Energy Applications Overview 433 Background and Progress of Silicon Nitride Ceramics for Bearing Applications 437 Ceramics in Energy and Environmental Applications in Australia 445 The Ceramic Revolution May Yet Arrive, Ushered in by Nanotechnology 475 Making Ceramics Ductile and Able to Carry Large Electrical Currents 479 Prospectus on the Future of High-Critical-Temperature Superconducting Ceramics 489 Solid Oxide Fuel Cells—The Future of Power Generation 497 Ceramic Materials and Systems for the Commercialization of Solid Oxide Fuel Cells 509 Fuel Cells—Has Their Time Finally Come? 529 The Role of Ceramics in a Resurgent Nuclear Industry 541 PART 7. ENVIRONMENT Environment Overview 597 Product Stewardship—Another Tool For Driving Business Excellence 601 Geopolymers—Low-Energy and Environmentally Sound Materials 623 Development of Photocatalysts for Commercial Application 635 Current and Potential Contribution of Ceramic Technology to Achieving Sustainable Development 643 Photocatalyst Materials for Environmental Protection 663 The Environmental Performances of Modern Ceramic Manufacture and Products, Used as Competitiveness Factors—The Experience of European and Italian Ceramic Tile Industry 681 Photocatalysts Working Under Visible Light Irradiation 695 PART 8. GLASS AND TRANSPARENT CERAMIC MATERIALS Glass and Transparent Ceramic Materials Overview 705 Advances in Technical Glasses 709 Basic Research Benefiting the Glass Industry 715 Use of Early “Maps” to Guide Us Along the Road to a Stronger Glass of the Future 725 Glass—Introducing Our Society to a New Material Age: Clues to Producing Ultrastrong Glass 749 Challenges and Future of Glass Melting Technology 765 E-Field Enhanced Processes for the Preparation of Nanomaterials 777 Development of the HiLight™ Transparent Ceramic Scintillator for Computed Tomography Medical Imaging 797 Transparent Polycrystalline Ceramics 803 Challenges for Overcoming Brittleness of Glass 811 PART 9. MULTIPLE APPLICATIONS AND PROCESSING Multiple Applications and Processing Overview 825 Innovative Products and Processes Based on Piezoelectric Ceramic Fibers 829 Nanoceramics—Challenges and Accomplishments 839 Development and Properties of Ultrahigh-Temperature Ceramics—Opportunities and Barriers to Applications 847 Progress in Advanced Ceramic Fibers and Their Future Perspective 865 Prospective and Recent Development on Advanced Inorganic Materials and Their Applications in the Shanghai Institute of Ceramics 885 Low-Cost, High-Performance, Epitaxial Ceramic Films on Artificial Substrates for Energy and Electronic Applications 891 Thermal Plasma Deposition of Ceramic Coatings 903 PART 10. TRANSPORTATION Transportation Overview 915 Applications of Ceramics for Gas Turbine Engines 919 Ceramic Research and Successes in Diesel Engines 931 Index 943
Stephen Freiman
Jeffrey D. Smith
Kazuo Inamori
Rod Lanthorne
Henry Kressel
Eiji Muromachi and Teruo Kishi
Jianbao Li
Julie A Yeomans
Rakesh Kapoor and Kevin J. Gray
Lora Cooper Saiber
Jodi Vecchiarelli
John R. Hellmann
Debra L. Kaiser and Robert F. Cook
K. T. Faber
Lynnette D. Madsen
Linking Productivity Analysis and Innovation for Materials and Energy—A Common Platform Approach 143
J. A. Sekhar, C. Yerramilli, and John Dismukes
Robert J. Sayre
Stephen Freiman and George Quinn
Linn W. Hobbs
Julian R. Jones and Larry L. Hench
Grady White
André Gahler, Jens Günster, and Jürgen G. Heinrich
W. Höland and V. Rheinberger
Anna Tampieri
Julian R. Jones
John R. Hellmann
Somnuk Sirisoonthorn
Yoshito Mitani, Jose Antonio Salas-Tellez, Jose Manuel Juarez-Garcia, and Froylan Martinez-Suarez
Martin L. Green and Robert F. Cook
Duane B. Dimos, Nelson S. Bell, Joseph Cesarano III, Paul G. Clem, Kevin G. Ewsuk, Terry J. Garino, and Bruce A. Tuttle
Shunpei Yamazaki
Hiroshi Tamura, Jun Harada, and Yasutaka Sugimoto
Semiconductor Processing—The Use of Advanced Ceramics 337
Donald Bray
Alan Rae
C. A. Randall, G. Yang, E. Dickey, R.E. Eitel, T.R. Shrout, M.T.Lanagan, D. Kwon, E. Semouchkina, G. Semouchkin, A. Baker, H. Nagata, J. Wang, S. Trolier-McKinstry, and S. Rhee
Nava Setter
Brian Sundlof and Benjamin Fasano
Sang-Kyun Kim and Ungyu Paik, and Jae-Gun Park
Mrityunjay Singh
Katsutoshi Komeya and Junichi Tatami
Sukhvinder P.S. Badwal, Martin A. Green, Janusz Nowotny, and Charles C. Sorrell
Keith A. Blakely
James G. Daley
Victor A. Maroni
Pavadee Aungkavattana
Michael Stelter, Mihail Kusnezoff, and Alexander Michaelis
David W. Richerson
John Marra, Jon Carmack, Charles Henager, Jr., William E. Lee, Kurt Sickafus, Chris Stanek, Lance Snead, and Steven Zinkle
Hidden Ceramics in Energy and Transport Sectors—Current Status and Roadmap for the Future 553
G. Sundararajan, U.S. Hareesh, R. Johnson, and Y.R. Mahajan
Costa Sideridis
William P. Kelly and Dean E.Venturin
Dan S. Perera
Soo Wohn Lee and Huang Chen
William E. Lee, Aldo R. Boccaccini, Joao A. Labrincha, Cristina Leonelli, Charles H. Drummond III, and Christopher R. Cheeseman
Toshiya Watanabe and Naoya Yoshida
G. Timellini, C. Palmonari, and A. Fregni, R. Resca
Lian Gao and Songwang Yang
Gary Fischman
David L. Morse
Hervé H. Arribart
C.R. Kurkjian and W.R. Prindle
John T. Brown
Helmut A. Schaeffer
Rolf Clasen
Steven J. Duclos, Robert Lyons, Robert Riedner, Hauchuan Jiang, and David M. Hoffman
Marina R. Pascucci
Setsuro Ito
Thomas W. Coyle
Richard Cass, Farhad Mohammadi, and Stephen Leschin
Vladimir D. Krstic
Alida Bellosi and Gian Nicola Babini
Toshihiro Ishikawa
Hongjie Luo
Amit Goyal
Thomas W. Coyle
Costa Sideridis
Mark van Roode
Thomas M. Yonushonis, Randall Stafford, William Mandler, and Joe Bentz
Subject Areas: Mechanical engineering & materials [TG]
