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Measurement of Soluble Nuclide Dissolution Rates from Spent Fuel

Published online by Cambridge University Press:  21 February 2011

C. N. Wilson  and
W. J. Gray
C. N. Wilson
Affiliation:
Pacific Northwest Laboratory, P. 0. Box 999, Richland, WA 99352.
W. J. Gray
Affiliation:
Pacific Northwest Laboratory, P. 0. Box 999, Richland, WA 99352.
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Abstract

Gaining a better understanding of the potential release behavior of water-soluble radionuclides is the focus of new laboratory spent fuel dissolution studies being planned in support of the Yucca Mountain Project. Previous studies have suggested that maximum release rates for actinide nuclides, which account for most of the long-term radioactivity in spent fuel, should be solubility-limited and should not depend on the characteristics or durability of the spent fuel waste form. Maximum actinide concentrations should be sufficiently low to meet the NRC annual release limits. Potential release rates for soluble nuclides such as 99Tc, 135Cs, 14C and 129I, which account for about 1-2% of the activity in spent fuel at 1000 years, are less certain and may depend on processes such as oxidation of the fuel in the repository air environment.

Dissolution rates for several soluble nuclides have been measured from spent fuel specimens using static and semi-static methods. However, such tests do not provide a direct measurement of fuel matrix dissolution rates that may ultimately control soluble-nuclide release rates. Flow-through tests are being developed as a potential supplemental method for determining the matrix component of soluble-nuclide dissolution. Advantages and disadvantages of both semi-static and flow-through methods are discussed. Tests with fuel specimens representing a range of potential fuel states that may occur in the repository, including oxidized fuel, are proposed. Preliminary results from flow-through tests with unirradiated UO2 suggesting that matrix dissolution rates are very sensitive to water composition are also presented.

Type
Research Article
Information
MRS Online Proceedings Library (OPL) , Volume 176: Symposium U – Scientific Basis for Nuclear Waste Management XIII , 1989 , 489
Copyright
Copyright © Materials Research Society 1990

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References

REFERENCES

1. Wilson, C. N., Bruton, C. J., Studies on Spent Fuel Dissolution Behavior under Proposed Yucca Mountain Repository Conditions, UCRL-100223, Lawrence Livermore National Laboratory, Livermore, CA (1989).Google Scholar
2.Code of Federal Regulations, “Disposal of High-Level Radioactive Wastes in Geological Repositories - Licensing Procedures”, Title 10, Chapter 1, Part 60, Section 60.113, June 30, 1983.Google Scholar
3. Wilson, C. N., ’Summary of Results from Series 2 and Series 3 NNWSI Spent Fuel Dissolution Tests”, Scientific Basis for Nuclear Waste Management XI, Apted, M. J. and Westerman, R. E., Ed., Materials Research Soc., Pittsburgh, PA, Vol. 112, pp 473483, 1988.Google Scholar
4. Johnson, L. H., Garisto, N. C. and Stroes-Gascoyne, S., “Used-Fuel Dissolution Studies in Canada”, Waste Management 85, Post, R. G. and Wacks, M. E. editors, Volume 1, pp 479482, University of Arizona, Tucson, AZ (1985).Google Scholar
5. Campbell, T. K., et. al., Interim Results From UO, Fuel Oxidation Tests In Air, PNL-6201, Pacific Northwest Laboratory, Richland, WA (1987).Google Scholar
6. Woodley, R. E., Einziger, R. E., Buchanan, H. C., Measurement of the Oxidation of Spent Fuel Between 140°C and 225°C by Thermogravimetric Analysis, WHC-EP-107, Westinghouse Hanford Co., Richland, WA (1988).Google Scholar
7. Einziger, R. E., Test Plan for Long-Term Low-Temperature Oxidation of Spent Fuel -- Series 1, HEDL-7560, Hanford Engineering Development Laboratory, Richland, WA (1986).Google Scholar