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Processing Effects on the Behavior of Titanate Waste Forms in Aqueous Solutions

Published online by Cambridge University Press:  15 February 2011

R. G. Dosch*
Affiliation:
Sandia National Laboratories, Albuquerque, New Mexico, 87185, U.S.A.
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Abstract

Titanate processing parameters including temperature, waste loading, redox conditions, and additives used to promote specific phases were evaluated with respect to their effect on leaching of Cs, Mo, Ca, Sr, Ba, U, Gd, and Ti in the range of 22°-150°C in leachates which included deionized water, acidic (pH 2), and basic (pH 12) solutions. Surface analyses and microstructural characterization were used to relate observed leaching behavior to processing parameters. Redox conditions were found to be very important with respect to Cs (and Mo) retention. Two Cs-bearing phases were found in titanate prepared under oxidizing conditions. One had a hollandite structure and the other contained Cs, Mo, Ca, and Fe as major constituents. The latter phase, which was more susceptible to leaching, was not observed in titanates prepared using adequate reducing conditions. Where applicable, a reference glass (PNL 76–68) was included in the leaching tests. Comparative leach rates for elements common to both waste forms were generally one to four orders of magnitude lower for the titanates within the range of conditions used.

Type
Research Article
Copyright
Copyright © Materials Research Society 1982

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References

REFERENCES

1. Dosch, R. G., “Ceramic Forms for Nuclear Waste,” ACS Symposium Series No. 100, Radioactive Waste in Geologic Storage, Fried, S., ed., ACS, 1979.Google Scholar
2. Dosch, R. G., Lynch, A. W., Headley, T. J., and Hlava, P. F., “Titanate Waste Forms for High Level Waste - An Evaluation of Materials and Processes,” pp. 123130 in Scientific Basis for Nuclear Waste Management, Vol.3, Moore, J. G., ed., Plenum Press, 1981.Google Scholar
3. Dosch, R. G., “Leaching Behavior of Titanate Nuclear Waste Forms in Aqueous Solutions,” SAND81–1423, to be published.Google Scholar
4. Northrup, C. J., Arnold, G. W. and Headley, T. J., “Ion Implantation Studies of Nuclear Waste Forms,” Scientific Basis for Nuclear Waste Management, Materials Research Society Meeting, Boston, MA, 1981.Google Scholar
5. Dosch, R. G. and Lynch, A. W., “Solution Chemistry in SYNROC Preparation,” SAND80–2375, July 1981.Google Scholar
6. Ringwood, A. E., Oversby, V. M., Kesson, S. E., Sinclair, W., Ware, N., Hibberson, W., and Major, A., “Immobilization of High Level Nuclear Reactor Wastes in SYNROC: A Current Appraisal,” Research School of Earth Sciences, Australian National University, Canberra, Australia, Publication No. 1475, April 1981. In Press: Nuclear and Chemical Waste Management.Google Scholar
7. Mendel, J. E., ed., “Materials Characterization Center Workshop on Leaching of Radioactive Waste Forms,” PNL–3318, pp. 4.9–4.25, April 1980.Google Scholar
8. Kenna, B. T. and Johnson, A. W., “Trace Analysis of Cesium by Laser Excited Atomic Fluorescence Spectrometry,” to be published in Analytical Chemistry.Google Scholar
9. Kenna, B. T., “Analysis of Long-Term Soxhlet Leaching Tests,” ORNL Conference on the Leachability of Radioactive Solids Gatlinburg, TN Dec. 9–12, 1980; to be published in Nuclear and Chemical Waste Management, Pergamon Press, NY.Google Scholar
10. Headley, T. J., “High Resolution Observations of Ion Milling Induced Transformations in Synthetic Hollandite,” 39th Annual Proceedings of the Electron Microscopy Society of America; Atlanta, GA, 1981, Baily, G. W., ed., Claitors Publishing Co.Google Scholar