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Plastic Deformation of Ceramics

  • Richard C. Bradt
  • Chris A. Brookes
  • Jules L. Routbort

Table of contents

  1. Front Matter
    Pages i-xii
  2. Ronald L. Stewart, Richard C. Bradt
    Pages 21-29
  3. A. Domínguez-Rodríguez, M. Jiménez-Melendo, J. Castaing
    Pages 31-41
  4. B. Baufeld, U. Messerschmidt, D. Baither, M. Bartsch, A. Foitzik, M. Rühle
    Pages 43-51
  5. K. P. D. Lagerlöf
    Pages 63-74
  6. Werner Skrotzki
    Pages 75-86
  7. Matthew J. Kramer, Jeffrey E. Shield
    Pages 99-108
  8. M. A. Boling-Risser, K. C. Goretta, J. L. Routbort
    Pages 109-117
  9. Sergei Pan, Alexander Slipenyuk, Vadim Danilyuk
    Pages 119-130
  10. E. Jill Brookes, Chris A. Brookes
    Pages 131-147
  11. Sarah V. Hainsworth, Andrew J. Whitehead, Trevor F. Page
    Pages 173-184
  12. Peter C. Twigg, Martin R. McGurk, Sarah V. Hainsworth, Trevor F. Page
    Pages 219-229
  13. Takayoshi Iseki, Toyohiko Yano, Masanori Ikari
    Pages 231-240
  14. Ganesh Skandan, Mike Roddy, W. Roger Cannon, Robert Nitsche, Horst Hahn
    Pages 285-291
  15. Alfonso Bravo-León, Manuel Jiménez-Melendo, Arturo Domínguez-Rodríguez, Atul H. Chokshi
    Pages 293-300
  16. John R. Seidensticker, Merrilea J. Mayo
    Pages 313-320
  17. Jerry Wittenauer
    Pages 321-331
  18. C. von Minden, M. M. R. Boutz, S. Scheppokat, R. Janssen, N. Claussen
    Pages 333-341
  19. Denis Murat, Tanguy Rouxel, Jean-Louis Besson, Frédéric Valin, Guy Schnedecker
    Pages 343-350
  20. Tanguy Rouxel, Fabroce Rossognol, Jean-Louis Besson, Paul Goursat, Jean-François Goujaud, Pierre Lespade
    Pages 351-358
  21. David S. Wilkinson
    Pages 359-368
  22. Oscar A. Ruano, Oleg D. Sherby
    Pages 369-380
  23. W. Roger Cannon, Stephen Haig, Philip J. Whalen
    Pages 381-392
  24. K. C. Goretta, J. L. Routbort, D. J. Miller, Nan Chen, A. Domínguez-Rodríguez, M. Jiménez-Melendo et al.
    Pages 393-402
  25. J. Wolfenstine
    Pages 415-423
  26. Robert F. Davis, C. H. Carter Jr., K. L. More, J. E. Lane, R. D. Nixon, D. A. Koester et al.
    Pages 425-444
  27. Marie-Laure Duval-Rivière, Jean Vicens
    Pages 445-456
  28. Andrew A. Wereszczak, Mattison K. Ferber, Timothy P. Kirkland, Karren L. More
    Pages 457-466
  29. Gregory N. Morscher, Hee Man Yun, Jon C. Goldsby
    Pages 467-478
  30. Sheldon M. Wiederhorn, William E. Luecke, Jonathan D. French
    Pages 479-493
  31. David M. Owen, Atul H. Chokshi
    Pages 507-518
  32. Thomas Hansson, Colette O’Meara, Kent Rundgren, Patrik Svensson, Richard Warren, Jonas Wasén
    Pages 519-532
  33. A. R. DeArellano-López, A. Domínguez-Rodríguez, K. C. Goretta, J. L. Routbort
    Pages 533-542
  34. Hua-Tay Lin, Paul F. Becher
    Pages 543-553
  35. M. Backhaus-Ricoult, P. Eveno, J. Castaing, H.-J. Kleebe
    Pages 555-565

About this book

Introduction

This proceedings volume, "Plastic Deformation of Ceramics," constitutes the papers of an international symposium held at Snowbird, Utah from August 7-12, 1994. It was attended by nearly 100 scientists and engineers from more than a dozen countries representing academia, national laboratories, and industry. Two previous conferences on this topic were held at The Pennsylvania State University in 1974 and 1983. Therefore, the last major international conference focusing on the deformation of ceramic materials was held more than a decade ago. Since the early 1980s, ceramic materials have progressed through an evolutionary period of development and advancement. They are now under consideration for applications in engineering structures. The contents of the previous conferences indicate that considerable effort was directed towards a basic understanding of deformation processes in covalently bonded or simple oxide ceramics. However, now, more than a decade later, the focus has completely shifted. In particular, the drive for more efficient heat engines has resulted in the development of silicon-based ceramics and composite ceramics. The discovery of high-temperature cupric oxide-based superconductors has created a plethora of interesting perovskite-Iike structured ceramics. Additionally, nanophase ceramics, ceramic thin films, and various forms of toughened ceramics have potential applications and, hence, their deformation has been investigated. Finally, new and exciting areas of research have attracted interest since 1983, including fatigue, nanoindentation techniques, and superplasticity.

Keywords

ceramics composite crystal deformation fatigue

Editors and affiliations

  • Richard C. Bradt
    • 1
  • Chris A. Brookes
    • 2
  • Jules L. Routbort
    • 3
  1. 1.University of AlabamaTuscaloosaUSA
  2. 2.University of HullHullEngland
  3. 3.Argonne National LaboratoryArgonneUSA

Bibliographic information