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Humidity Controlled Diffractometry and its Applications

Published online by Cambridge University Press:  06 March 2019

Radko A. Kühnel  and
Sjerry J. van der Gaast
Radko A. Kühnel
Affiliation:
International Institute for Aerospace Survey and Earth Sciences (ITC), 2628 EB, Delft, The Netherlands
Sjerry J. van der Gaast
Affiliation:
Netherlands Institute for Sea Research (NIOZ), 1790 AB, Den Burg, Texel, The Netherlands
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Abstract

Humidity sensitive mineral phases change their structure when humidity varies resulting in X-ray pattern changes in intensity, position, and shape of lines. These structural changes in hydrous minerals are induced by dehydration and rehydration, which can lead to phase transformations or to steady depletion which may result in a total structure collapse. By means of X-ray diffraction with a special attachment, such reactions can be followed. The controlled relative humidity is provided in situ, in a closed cell, by a flow of moistened helium gas which is flushed through the cell during the XRD analysis. Humidity diffractometry allows studies of reaction rates of dehydration-rehydration reactions and their reversibilities, as well as effects of additives and impurities on these reactions. Potential applications in basic research and in industry are demonstrated using montmorilionite, ettringites, sodium carbonates and calcium sulfates.

Type
VIII. High-Temperature and Non-Ambient Applications of XRD
Information
Advances in X-Ray Analysis , Volume 36: Forty-First Annual Conference on Applications of X-ray Analysis, August 3-7, 1992 , 1992 , pp. 439 - 449
Copyright
Copyright © International Centre for Diffraction Data 1992

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References

1. van der Gaast, S.J. and Vaars, A. J., “A Method to Eliminate Background in X-ray Diffraction Patterns of Oriented Clay Mineral Samples,” in Clays and Clay Minerals 16: 349-354(1981).Google Scholar
2. Kiihnel, R. A. and van der Gaast, S.J., “Effects of Different Cations and Relative Humidity on the Shape of (001) Reflection of Wyoming Montmorillonite,” in Proc.5th European Clay Conference. Prague, (abstract) (1981).Google Scholar
3. Kiihnel, R. A., van der Gaast, S.J. and Vaars, A. J., “Changes of Line Profile of Basal Reflection at Different Relative Humidities on Na-Saturated Montmorillonite”, in Sth AIPEA Int. Clay Conf, Ahstracts Book. Denver, p. 131(1985).Google Scholar
4. Kiihnel, R. A., van der Gaast, S.J., “Humidity Diffractometry of Wyoming Montmorillonite” (in preparation).Google Scholar
5. Hassett, D. J., Pfughoeft-Hassett, D.F., Kumarathasan, P. and McCarthy, G. J., “Ettringite as an Agent for the Fixation of Hazardous Oxyanions,” in Proc. 12th Ann. Madison Waste Conf. on Municipal and Industrial Waste. 471-482(1989).Google Scholar
6. Kumarathasan, P., McCarthy, G. J., Hassett, D. J., and Pflughoeft-Hassert, D.F., “Oxyanion Substituted Ettringite: Synthesis and Characterization; and their Role in Immobilization of As, B, Cr, Se, V,” in Fly Ash and Coal Conversion By-Products: Characterization. Utilization and Disposal VI. Mater. Res. Soc. Symp. Proc. Vol. 178, 83-104(1990).Google Scholar
7. Hassett, D. J., McCarthy, G. J., Kumarathasan, P. and Pflugboeft-Hassett, P.F., “Synthesis and Characterization of Selenate and Sulfate-Selenate Ettringite Structure Phases,” in Mater. Res, Bull. 25: 13471354(1990).Google Scholar
8. Bender, J. A., Solem, J. K., McCarthy, G. J., Oseto, M. C. and Knell, J. E., “Quantitative Analysis of Advanced Coal Combustion Residuals: A Practical Application of the RIR Method” (this volume).Google Scholar
9. Pdllmann, H., Knzel, H.-J. and Wenda, R., “Compounds with Ettringite Structure”,in Neues Jahrhuch Miner. Abh. 160:133158(1989).Google Scholar