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X-Ray Diffraction Analysis of NPK 12-19-19 Fertilizers

Published online by Cambridge University Press:  10 January 2013

B. Knob
Affiliation:
Chemopetrol — Research Institute of Inorganic Chemistry, 400 60 Ústí nad Labern, Czechoslovakia
J. Waňková
Affiliation:
Chemopetrol — Research Institute of Inorganic Chemistry, 400 60 Ústí nad Labern, Czechoslovakia
F. Moudrý
Affiliation:
Chemopetrol — Research Institute of Inorganic Chemistry, 400 60 Ústí nad Labern, Czechoslovakia
M. Kuba
Affiliation:
Chemopetrol — Research Institute of Inorganic Chemistry, 400 60 Ústí nad Labern, Czechoslovakia

Abstract

A quantitative X-ray diffraction method for the phase analysis of fertilizers of the NPK 12-19-19 type has been worked out together with a complex system of computer software. A bank of synthetic standards was employed in the solution of the problem. To reflect the real structure of the phases determined in fertilizers as against the structure of synthetic standards, intensity coefficients based on chemical analyses were assigned to individual phases in the bank of standards.

Type
Research Article
Copyright
Copyright © Cambridge University Press 1986

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References

1.Klug, H. P., Alexander, L. E.: “X-Ray Diffraction Procedures”, John Wiley & Sons, New York 1954.Google Scholar
2.Guinier, A.: “Théorie et Technique de la Radiocristallographie”, Dunod, Paris 1956.Google Scholar
3.Neff, H.: “Grundlagen und Anwendung der Röntgen-Feinstruktur-Analyse”, R. Oldenbourg, München 1962.Google Scholar
4.Zevin, L. S., Zayjalova, L. L.: “Količestvennyj Rentgenografičeskij Fazovyj Analiz”, Nědra, Moskva 1974.Google Scholar
5.Fiala, J.: Silikáty 29 (1985) 273288.Google Scholar
6.Ando, J., Smith, J. P., Siegel, M. R., Jordan, J. E.: J. Agr. Food Chem. 13, 186 (1965).Google Scholar
7.Vonk, C. G., Heck, H. G., Pijpers, A. S.: Quantitative X-ray Analysis of Crystalline Components in Fertilizers. DSM, Centr. Labor., Geleen, Netherlands (1975).Google Scholar
8.Fiala, J.: Hutnické listy 32 (1977), 435437.Google Scholar
9.Fiala, J.: Journal of Physics D 5 (1972), 18741875.CrossRefGoogle Scholar
10.Vonk, C. G.: FFXPOWD program for the processing of X-ray powder patterns. DSM, Centr. Labor., Geleen, Netherlands (1975).Google Scholar
11.Yvon, K., Jeitschko, W., Parthé, E.: J. Appl. Crystallogr., 10, 13 (1977) Copenhagen.CrossRefGoogle Scholar
12.Visser, J. W., de Wolff, P. M.: “Absolute Intensities”, Report No. 641.109. Technisch Physische Dienst, Delft, Netherlands (1964).Google Scholar
13.Chung, F. H., J. Appl. Cryst. 8 (1975), 1719.CrossRefGoogle Scholar
14.Hubbard, C. R., Evans, E. H., Smith, D. K.: J. Appl. Cryst. 9 (1976), 169174.Google Scholar
15.Calvert, L. D., Flippen-Anderson, J. L., Hubbard, C. R., Johnson, Q. C., Lenhert, P. G., Nichols, M. C., Parrish, W., Smith, D. K., Smith, G. S., Snyder, R. L., Young, R. A.: “Standards for the Publication of Powder Patterns: the American Crystallographic Association Subcommittee's Final Report” in “Accuracy in Powder Diffraction“, NBS Special Publication 567, Washington 1980, pp. 513534.Google Scholar
16.Wyckoff, R. W. G.: Crystal Structures, Vol. 1–3. Interscience Publishers, Inc. New York, 1948.Google Scholar