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International Tables for Crystallography (2019). Vol. H. ch. 3.10, pp. 374-384
https://doi.org/10.1107/97809553602060000955 |
Chapter 3.10. Accuracy in Rietveld quantitative phase analysis with strictly monochromatic Mo and Cu radiations
Contents
- 3.10. Accuracy in Rietveld quantitative phase analysis with strictly monochromatic Mo and Cu radiations (pp. 374-384) | html | pdf | chapter contents |
- 3.10.1. Introduction (pp. 374-375) | html | pdf |
- 3.10.2. Compounds and series (pp. 375-376) | html | pdf |
- 3.10.3. Analytical techniques (pp. 376-377) | html | pdf |
- 3.10.4. Powder-diffraction data analysis (p. 377) | html | pdf |
- 3.10.5. Crystalline single phases (pp. 377-379) | html | pdf |
- 3.10.6. Limits of detection and quantification (pp. 379-381) | html | pdf |
- 3.10.7. Increasing inorganic crystalline phase content series (p. 381) | html | pdf |
- 3.10.8. Increasing crystalline organic phase content series (pp. 381-382) | html | pdf |
- 3.10.9. Increasing amorphous content series within an inorganic crystalline phase matrix (pp. 382-383) | html | pdf |
- 3.10.10. Conclusions (pp. 383-384) | html | pdf |
- References | html | pdf |
- Figures
- Fig. 3.10.1. Irradiated volume for a flat sample holder in transmission mode using (a) Mo radiation and (b) Cu radiation, and (c) reflection mode using Cu radiation (p. 374) | html | pdf |
- Fig. 3.10.2. Scanning electron microscopy micrographs for the studied phases (×1000) (p. 376) | html | pdf |
- Fig. 3.10.3. (a) Raw Mo Kα1 powder patterns for the inorganic series composed of a constant matrix of calcite, gypsum and quartz, and increasing amounts of insoluble anhydrite (peaks highlighted with a solid square) (p. 377) | html | pdf |
- Fig. 3.10.4. Selected region of the powder patterns showing the main diffraction peak of insoluble anhydrite for the low-content samples to investigate the limit of detection (p. 378) | html | pdf |
- Fig. 3.10.5. (a) Raw Mo Kα1 powder patterns for the organic series composed of a constant matrix of glucose, fructose and lactose, and increasing amounts of xylose (peaks highlighted with an asterisk) (p. 379) | html | pdf |
- Fig. 3.10.6. Selected range of the Rietveld plots for CGpQ_4.0A: (a) Mo Kα1 and (b) Cu Kα1 patterns (p. 380) | html | pdf |
- Fig. 3.10.7. Rietveld quantification results for (a) the insoluble anhydrite series (within an inorganic crystalline matrix), (b) the xylose series (within an organic crystalline matrix) and (c) the ground-glass series (within an inorganic crystalline matrix) as a function of the weighed amount of each phase (p. 381) | html | pdf |
- Fig. 3.10.8. Raw powder patterns for the amorphous-material-containing series composed of a constant matrix of calcite and zincite, and increasing amounts of ground glass (p. 383) | html | pdf |
- Tables
- Table 3.10.1. Cambridge Structural Database (CSD)/Inorganic Crystal Structure Database (ICSD) reference codes for all phases used for Rietveld refinements in this work and the linear absorption coefficients for the wavelengths used (p. 375) | html | pdf |
- Table 3.10.2. Rietveld quantitative phase analyses for the crystalline inorganic mixtures measured with Cu Kα1 and Mo Kα1 radiations (p. 380) | html | pdf |
- Table 3.10.3. RQPA for the crystalline organic mixtures measured with Cu Kα1 and Mo Kα1 radiations (p. 382) | html | pdf |
- Table 3.10.4. Rietveld quantitative phase analyses of the CQZ_xGl mixture, where quartz (Q) is the internal standard, to derive amorphous content (am), obtained from SXRPD, Mo Kα1 and Cu Kα1 patterns (p. 382) | html | pdf |