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    Stocks-Fischer, Shannon Galinat, Johnna K. and Bang, Sookie S. 1999. Microbiological precipitation of CaCO3. Soil Biology and Biochemistry, Vol. 31, Issue. 11, p. 1563.
    McCarthy, Gregory 1999. Industrial Applications of X-Ray Diffraction. p. 555.
    Smith, Deane K. 1997. Evaluation of the detectability and quantification of respirable crystalline silica by X-ray powder diffraction methods. Powder Diffraction, Vol. 12, Issue. 04, p. 200.
    Esteve, V. Rius, J. Ochando, L.E. and Amigó, J.M. 1997. Quantitative x-ray diffraction phase analysis of coarse airborne particulate collected by cascade impactor sampling. Atmospheric Environment, Vol. 31, Issue. 23, p. 3963.
    Davis, Briant L. and Johnson, L. Ronald 1989. Quantitative Mineral Analysis of Clays. p. 103.
    Shearer, C. K. Papike, J. J. Simon, S. B. Davis, B. L. and Laul, J. C. 1988. Mineral Reactions in Altered Sediments From the California State 2-14 Well: Variations in the Modal Mineralogy, Mineral Chemistry and Bulk Composition of the Salton Sea Scientific Drilling Project Core. Journal of Geophysical Research: Solid Earth, Vol. 93, Issue. B11, p. 13104.
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X-Ray Quantitative Analysis of Coal By The Reference Intensity Method

  • Briant L. Davis (a1), L. Ronald Johnson (a1) and T. Mebrahtu (a1)
Abstract

Twenty-four coal samples representing the four major rank types were analyzed by the X-ray RIM methodology which includes mass absorption analysis by X-ray transmission and quantitative X-ray powder diffraction. Twenty-three separate mineral species were observed in the samples, many of which could be quantified in the whole coal analysis. Several mineral species at levels of 5 weightpercent or less were observed only in the ashed scans. Some dehydration and reconstitution reactions were observed in the ashing process, including the combination of organically bound alkaline-earth elements and sulfur to form bassanite and magnesium sulfates. Quartz and kaolinite dominated the silicate mineral portion of the mineralogy, whereas calcite and siderite represented the carbonate; pyrite with associated sulfate oxidation products were generally present as well. The X-ray transmission studies were successful in estimating the carbonaceous matter in the whole coal samples and comparison of the chemical oxides derived from the X-ray data with direct analyses from the Penn State data sheets revealed good correlations, although significant departures occurred for some species and a systematic underestimation of aluminum oxide from the X-ray clay peaks was observed. This study suggests that the RIM procedure can be applied to coal mineral and amorphous component analysis on a routine basis.

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Copyright
COPYRIGHT: © Cambridge University Press 1986
References
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Powder Diffraction
  • ISSN: 0885-7156
  • EISSN: 1945-7413
  • URL: /core/journals/powder-diffraction
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