International Tables for Crystallography (2019). Vol. H. ch. 7.14, pp. 885-892
https://doi.org/10.1107/97809553602060000988

Chapter 7.14. Powder diffraction by minerals

Contents

  • 7.14. Powder diffraction by minerals  (pp. 885-892) | html | pdf | chapter contents |
    R. Arletti, G. Cruciani and G. Ferraris
    • 7.14.1. Powder diffraction and characterization of new mineral species  (pp. 885-886) | html | pdf |
    • 7.14.2. Mineral physics through in situ powder-diffraction experiments  (pp. 886-889) | html | pdf |
      • 7.14.2.1. Thermoelastic behaviour of minerals  (pp. 886-887) | html | pdf |
      • 7.14.2.2. Negative thermal expansion in minerals  (p. 887) | html | pdf |
      • 7.14.2.3. Dehydration of nonporous minerals  (pp. 887-888) | html | pdf |
      • 7.14.2.4. Dehydration and adsorption/desorption mechanisms in porous materials  (p. 888) | html | pdf |
      • 7.14.2.5. High-pressure (HP)-induced reaction/penetration in porous materials  (p. 888) | html | pdf |
      • 7.14.2.6. Phase transitions and spontaneous strain in minerals  (pp. 888-889) | html | pdf |
      • 7.14.2.7. HT studies related to CO2 sequestration  (p. 889) | html | pdf |
    • 7.14.3. Minerals related to human health, the biosphere and planetary exploration  (pp. 889-890) | html | pdf |
      • 7.14.3.1. Fibrous minerals  (pp. 889-890) | html | pdf |
      • 7.14.3.2. Biominerals  (p. 890) | html | pdf |
      • 7.14.3.3. Mars mineralogy  (p. 890) | html | pdf |
    • References | html | pdf |
    • Figures
      • Fig. 7.14.1. Number of publications related to studies carried out on minerals using XRPD per year (from Google Scholar)  (p. 885) | html | pdf |
      • Fig. 7.14.2. Habits of (a) amphibole asbestos (amosite) and (b) chrysotile asbestos  (p. 889) | html | pdf |