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X-Ray Diffraction Investigation of BeO Calcination Processes

Published online by Cambridge University Press:  06 March 2019

R.C. Rau*
Affiliation:
General Electric Company, Cincinnati, Ohio
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Abstract

To aid in the study of the preparation and properties at BeO, X-ray diffraction investigations were performed to determine the various phases and transformation temperatures occurring in the different BeO calcination processes and to determine the theoretical density of the final BeO product.

The hydroxide, sulfate, and oxalate of beryllium were the starting materials in the three calcination series. The samples studied were prepared by heating small portions of the starting materials for 1 hr at various temperatures and slow cooling. Analysis of the hydroxide series showed a direct conversion from Be(OH)a to BeO by simple loss of water. However, both the sulfate series and the oxalate series go through a series of intermediate phases in transforming to BeO. X-ray data and structure information have been obtained for most of these phases, and temperature ranges of their occurrence have been established.

Wherever possible, the X-ray results have been compared with results of stereoscopic and polarizing microscope examinations, and temperature range of occurrence have been compared with thermal balance curves.

Type
Research Article
Copyright
Copyright © International Centre for Diffraction Data 1960

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References

1. Bartram, S. F., “Crystallite Size and Particle Size Measurements on BeO Powders by X-ray Methods,” This volume, p. 40.Google Scholar
2. Settz, A., Rosier, U., and Schubert, K., “The Crystal Structure of β-Be(OH)2,” Z. anorg. Chem., Vol. 261, 1960, pp. 94105.Google Scholar
3. Terem, H. N., “The System Beryllium Sulfate—Water and the Dissociation of Beryllium Sulfate,” Compt. rend., Vol. 222, 1946, pp. 13471348.Google Scholar
4. Campbell, A. N., Sukava, A. J., and Koop, J., “Hydrates of Beryllium Sulfate,” J. Am. Chem. Soc, Vol. 73. 1951. pp. 28312835.Google Scholar
5. Hanawalt, J. D., Rinn, H. W., and Frevei, L. K., “Chemical Analysis by X-ray Diffraction,” Anal, Chem., Vol. 10, 1938, pp. 457512.Google Scholar
6. Grand, A., “The Crystal Structure of BeSO4,” Tschermak's mineralog. u. petrog. Mitt., Vol. 5, 1955, pp. 227230.Google Scholar
7. Kokkoros, P., “Crystallography and Structure of Beryllium Sulfate,“Tschermak's mineralog, u. petrog. Mitt., Vol. 6, 1956, pp. 116119.Google Scholar
8. Cooperstein, R., “Beryllium Oxide Studies: The Preparation of Pure Beryllium Oxide,” 137th ACS National Meeting, Cleveland, Ohio, April 11-14, 1960.Google Scholar
9. Hendricks, St. B., “The Orientation of the Oxalic Group in Oxalic Acid and Some of Its Salts,” Z. Kristallogr., Vol. 91, 1935, pp. 4864.Google Scholar
10. Ahmed, F. R. and Cruickshank, D. W. J., “A Refinement of the Crystal Structure Analyses of Oxalic Acid Dihydrate,” Acta Cryst., Vol. 6, 1958, pp. 385392.Google Scholar
11. Hamner, R. L. and Harris, L. A., “The Calcination in Air of Beryllium Oxalate Tri hydrate to Beryllium Oxide,” American Ceramic Society Annual Convention, Philadelphia, Pa., April 24-28, 1960.Google Scholar
12. Venturello, G., “The Neutral Carbonate and Basic Carbonates of Beryllium,” Gazz. chim. ital., Vol. 69, 1939, pp. 7386.Google Scholar
13. Terem, H. N., “Tbe Dissociation of Beryllium Carbonate,” Compt. rend., Vol. 222, 1946, pp. 14361437.Google Scholar
14. Terem, H. N., “A Continuous Method of Differential Analysis; Application to the Case of Basic Beryllium Carbonate,” Rev. faculté sci, univ. Istanbul, Ser, A, Vol. 11, 1946, pp. 107118.Google Scholar
15. Shargorodskii, S. K. and Shor, O. I., “A Study of the Thermal Decomposition of Beryllium, Calcium, Strontium, and Barium Nitrates and Carbonates,” Ukrain, Khim. Zhur., Vol. 20, 1954, pp. 357362.Google Scholar
16. Swanson, H. E. and Tatge, E., “Standard X-ray Diffraction Powder Patterns,” National Bureau of Standards Circular. 539, Vol, I, 1953, pp, 36-37.Google Scholar