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Non-Oxide Technical and Engineering Ceramics

  • Book
  • © 1986

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Editors:
  1. Stuart Hampshire

    1. Materials Research Centre, National Institute for Higher Education, Limerick, Ireland

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Table of contents (29 chapters)

  1. Front Matter

    Pages i-xiv
    Download chapter PDF

  2. Sialons: A Study in Materials Development

    • K. H. Jack
    Pages 1-30

  3. Discussion Session: Aspects of Commercialisation of Advanced Ceramics and Future Opportunities

    • R. J. Brook
    Pages 31-39

  4. Analysis of Coarsening and Densification Kinetics During the Heat Treatment of Nitrogen Ceramics

    • H. Pickup, U. Eisele, E. Gilbart, R. J. Brook
    Pages 41-51

  5. Sinterability of Silicon Nitride Powders and Characterisation of Sintered Materials

    • V. Vandeneede, A. Leriche, F. Cambier, H. Pickup, R. J. Brook
    Pages 53-68

  6. Microstructural Development and Secondary Phases in Silicon Nitride Sintered with Mixed Neodymia/Magnesia Additions

    • B. Saruhan, M. J. Pomeroy, S. Hampshire
    Pages 69-82

  7. Microstructural Development, Microstructural Characterization and Relation to Mechanical Properties of Dense Silicon Nitride

    • G. Wötting, B. Kanka, G. Ziegler
    Pages 83-96

  8. Sialon and Syalon Powders: Production, Properties and Applications

    • P. Ferguson, A. W. J. M. Rae
    Pages 97-104

  9. Reaction Sequences in the Preparation of Sialon Ceramics

    • W. Y. Sun, P. A. Walls, D. P. Thompson
    Pages 105-117

  10. Preparation and Densification of Nitrogen Ceramics from Oxides

    • S. A. Siddiqi, I. Higgins, A. Hendry
    Pages 119-132

  11. Preparation of Sialon Ceramics from Low Cost Raw Materials

    • C. J. Spacie
    Pages 133-147

  12. Densification Behaviour of Sialon Powders Derived from Aluminosilicate Minerals

    • M. Mostaghaci, Q. Fan, F. L. Riley, Y. Bigay, J. P. Torre
    Pages 149-164

  13. Sintering and some Properties of Si3N4 Based Ceramics

    • S. Bosković, E. Kostić
    Pages 165-174

  14. Syalon Ceramic for Application at High Temperature and Stress

    • M. H. Lewis, S. Mason, A. Szweda
    Pages 175-190

  15. Structural Evolution under High Pressure and at High Temperature of a β’-Sialon Phase

    • G. Roult, M. Brossard, J. C. Labbe, P. Goursat
    Pages 191-202

  16. Multianion Glasses

    • W. K. Tredway, S. H. Risbud
    Pages 203-212

  17. Non-destructive Evaluation of Ceramic Surfaces and Sub-surfaces

    • L. McDonnell, E. M. Cashell
    Pages 213-221

  18. Preparation and Characterization of Yttrium α’-Sialons

    • S. Slasor, D. P. Thompson
    Pages 223-230

  19. Characterisation and Properties of Sialon Materials

    • T. Ekström, N. Ingelström
    Pages 231-254

  20. Comparison of CBN, Sialons and Tungsten Carbides in the Machining of Surgical Implant Alloys and Cast Irons

    • M. Austin, J. Tooher, J. Monaghan, M. El-Baradie
    Pages 255-279
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Keywords

About this book

Conferences on technical and engineering ceramics are held with increasing frequency, having become fashionable because the potential of ceramics in profitable growth industries is an urgent matter of considerable debate and discussion. Japanese predictions are that the market value of ceramics will grow 10 at about 10% per annum to reach at least $10 by the end of the century. Seventy per cent of this market will be in electroceramics, applications for which include insulating substrates in integrated circuits, ferroelectric capacitors, piezoelectric oscillators and transdu­ cers, ferrite magnets, and ion-conducting solid electrolytes and sen­ sors. All these are oxides, and so are excluded by the title of the Limerick Conference. Why 'Non-oxide'? The other major ceramics potential is in struc­ tural engineering components and engine applications. Here, the greatest impetus to research and development has been the attempt to produce a ceramic gas turbine. Heat engines become more efficient as their working temperature increases, but nickel-base superalloy en­ gines have about reached their limit. Compared with metals, ceramics have higher strengths at high temperatures, better oxidation and corrosion resistance, and are also less dense. In general, ceramics have better properties above about 1000°C except in one respect-their inherent brittleness. The work of fracture is therefore much smaller than for metals and so the permitted flaw size is also smaller.

Editors and Affiliations

  • Materials Research Centre, National Institute for Higher Education, Limerick, Ireland

    Stuart Hampshire

Bibliographic Information

  • Book Title: Non-Oxide Technical and Engineering Ceramics

  • Editors: Stuart Hampshire

  • DOI: https://doi.org/10.1007/978-94-009-3423-8

  • Publisher: Springer Dordrecht

  • eBook Packages: Springer Book Archive

  • Copyright Information: Elsevier Applied Science Publishers Ltd 1986

  • Softcover ISBN: 978-94-010-8031-6Published: 06 October 2011

  • eBook ISBN: 978-94-009-3423-8Published: 06 December 2012

  • Edition Number: 1

  • Number of Pages: 458

  • Topics: Ceramics, Glass, Composites, Natural Materials

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