Novel microstructures for solids
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Bibliographic Information
Novel microstructures for solids
(IOP concise physics)
Morgan & Claypool, c2018
- : pbk
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Note
"A Morgan & Claypool publication as part of IOP Concise Physics"--T.p. verso
"IOP ebooks"--Cover
Includes bibliographical references
Description and Table of Contents
Description
For many years, evidence suggested that all solid materials either possessed a periodic crystal structure as proposed by the Braggs or they were amorphous glasses with no long-range order. In the 1970s, Roger Penrose hypothesized structures (Penrose tilings) with long-range order which were not periodic. The existence of a solid phase, known as a quasicrystal, that possessed the structure of a three dimensional Penrose tiling, was demonstrated experimentally in 1984 by Dan Shechtman and colleagues. Shechtman received the 2011 Nobel Prize in Chemistry for his discovery. The discovery and description of quasicrystalline materials provided the first concrete evidence that traditional crystals could be viewed as a subset of a more general category of ordered materials.
This book introduces the diversity of structures that are now known to exist in solids through a consideration of quasicrystals (Part I) and the various structures of elemental carbon (Part II) and through an analysis of their relationship to conventional crystal structures. Both quasicrystals and the various allotropes of carbon are excellent examples of how our understanding of the microstructure of solids has progressed over the years beyond the concepts of traditional crystallography.
Table of Contents
Preface
Acknowledgements
Author biography
Part I Quasicrystallography
1. Crystalline structure
2. X-ray diffraction techniques
3. Crystallographic symmetry
4. Aperiodic structures
5. Applications of quasicrystals
Part II Allotropes of carbon
6. Allotropes and crystal bonding
7. Diamond
8. Other crystalline allotropes of carbon
9. Nanostructured allotropes of carbon
by "Nielsen BookData"