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Relationship Between Glass Leaching Mechanism and Geochemical Transport of Radionuclides

Published online by Cambridge University Press:  15 February 2011

A. Avogadro  and
F. Lanza
A. Avogadro
Affiliation:
Commission of the European Communities Joint Research Centre - Ispra EstablishmentI-21020 Ispra (Va), Italy
F. Lanza
Affiliation:
Commission of the European Communities Joint Research Centre - Ispra EstablishmentI-21020 Ispra (Va), Italy
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Abstract

When the leaching of glasses is taken into consideration in risk analysis models, it is necessary to make a distinction between accidental and normal conditions in the repository. In accidental conditions, it is assumed that the glass will be leached by ground-water which can also be renewed. The composition of this water will be related to the aquifer existing around the repository. Under normal repository conditions the leaching process has to be analyzed separately for each geological formation considered.

Type
Research Article
Information
MRS Online Proceedings Library (OPL) , Volume 11: Symposium – Scientific Basis for Nuclear Waste Management V , 1981 , 103
Copyright
Copyright © Materials Research Society 1982

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References

REFERENCES

1. Van Iseghem, P., Timmermans, W. and De Batist, R., (1981) Interaction of vitrified HLW with clay environment.Google Scholar
Presented at the International Seminar on Chemistry and Process Engineering for HLW Solidification, Jülich, June 1981.Google Scholar
2. Hughes, A.E., Marples, J.A.C. and Stoneham, A.M., (1981) The significance of leach rates in determining the release of radioactivity from vitrified nuclear waste. AERE - R - 10190.Google Scholar
3. Iler, R.K., (1955) The colloid chemistry of silica and silicates. Cornell University Press, New York.CrossRefGoogle Scholar
4. Lanza, F. and Parnisari, E., (1981) Influence of film formation and its composition on the leaching of borosilicate glasses. Nucl. and Chem. Waste Management, 2, 131.CrossRefGoogle Scholar
5. Chapman, N.A., McKinley, I.G. and Savage, D., (1980) The effect of groundwater availability on the release source term in a low hydraulic conductivity environment. Proc. of the NEA Workshop on Radionuclide Release Scenario for Geological Repositories, Paris, September 1980.Google Scholar
6. Engelmann, C., Neus, B. and Trocellier, P., (1981) Mesure des profils de concentration de l'hydrogène et du sodium à la surface des verres par des méthodes nucléaires. Verres Refract., 35, 3, 486.Google Scholar
7. Bradley, D. J., Harvey, C. O. and Turcotte, R. P., (1979) Leaching of actinides and technetium from simulated high-level waste glass, PNL- 3152.CrossRefGoogle Scholar
8. Avogadro, A., Bidoglio, G. and Chatt, A., (1982) Speciation of radionuclides in natural waters. Presented at the 7th Annual Meeting of the Seabed Working Group of the Nuclear Energy Agency, OECD, La Jolla (CA) USA, March 1518, 1982.Google Scholar
9. Schreiner, F., Fried, S. and Friedman, A.M., (1980) Measurement of radionuclide mobility in ocean floor sediment and clay. Presented at the Symposium on the Backfill for Radioactive Waste Management, Las Vegas, August 1980.Google Scholar
10. Avogadro, A., Murray, C.N. and De Plano, A., (1980) Transport through deep aquifers of transuranic nuclides leached from vitrified high level wastes. Scientific Basis of Nuclear Waste Management, vol. 2, Northrup, J. M.Clyde Jr., Ed. Plenum Press, p. 665.CrossRefGoogle Scholar
11. Bonniaud, R. A. Jacquet-Francillon, , and Sombret, C. G., (1980) The behaviour of actinides in alpha-doped glasses with regard to the longterm disposal of high-level radioactive materials. Ibid., p. 117.Google Scholar