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Hydrogen Speciation in Hydrated Layers on Nuclear Waste Glass

Published online by Cambridge University Press:  28 February 2011

Roger D. Aines ,
Homer C. Weed  and
John K. Bates
Roger D. Aines
Affiliation:
Lawrence Livermore National Laboratory, Earth Sciences Department, P.O Box 808, L-202, Livermore, CA 94550
Homer C. Weed
Affiliation:
Lawrence Livermore National Laboratory, Earth Sciences Department, P.O Box 808, L-202, Livermore, CA 94550
John K. Bates
Affiliation:
Argonne National Laboratory, Chemical Technology Division, 9700 S. Cass Avenue, Argonne, Illinois, 60439
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Abstract

The hydration of an outer layer on nuclear waste glasses is known to occur during leaching, but the actual speciation of hydrogen (as water or hydroxyl groups) in these layers has not been determined. As part of the Nevada Nuclear Waste Storage Investigations Project, we have used infrared spectroscopy to determine hydrogen speciations in three nuclear waste glass compositions (SRL-131 & 165, and PNL 76-68), which were leached at 90°C (all glasses) or hydrated in a vapor-saturated atmosphere at 202°C (SRL-131 only). Hydroxyl groups were found in the surface layers of all the glasses. In addition, molecular water was found in the surface of SRL-131 and PNL 76-68 glasses that had been leached for several months in deionized water, and in the vapor-hydrated sample. The water/hydroxyl ratio increases with increasing reaction time; molecular water makes up most of the hydrogen in the thick reaction layers on vapor-phase hydrated glass while only hydroxyl occurs in the least reacted samples. Using the known molar absorptivities of water and hydroxyl in silica-rich glass the vapor-phase layer contained 4.8 moles/liter of molecular water, and 0.6 moles water in the form hydroxyl. A 15 micrometer layer on SRL-131 glass formed by leaching at 90°C contained a total of 4.9 moles/liter of water, 2/3 of which was as hydroxyl. The unreacted bulk glass contains about 0.018 moles/liter water, all as hydroxyl.

The amount of hydrogen added to the SRL-131 glass was about 70% of the original Na + Li content, not the 300% that would result from alkali-hydronium ion (H30+) interdiffusion. If all the hydrogen is then assumed to be added as the result of alkali-H+ interdiffusion, the molecular water observed may have formed from condensation of the original hydroxyl groups according to:

20H = H20 molecular + 00

where 00 refers to a bridging oxygen, and OH refers to a hydroxyl group attached to a silicate polymer. The hydrated layer on the nuclear waste glasses appears to be of relatively low water content (4 to 7% by weight) and is not substantially hydroxylated. Thus, these layers do not have many of the properties associated with “gel” layers.

Type
Research Article
Information
MRS Online Proceedings Library (OPL) , Volume 84: Symposium L – Scientific Basis for Nuclear Waste Management X , 1986 , 547
Copyright
Copyright © Materials Research Society 1987

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References

1. Mendel, J.E., (compiler) Final Report of the Defense High Level Leaching Mechanisms Program, Pacific Northwest Laboratory, Report PNL 5157 (1984).Google Scholar
2. Phinney, D.L., Ryerson, F.J., Oversby, V.M., Lanford, W.A., Aines, R.D., and Bates, J.K., Integrated testing of the SRL waste form. This volume.Google Scholar
3. Abrajano, T.A. and Bates, J.K., Transport and Reaction Kinetics at the Gel: Glass Transition Zone: Results of Repository-Oriented Experiments. This volume.Google Scholar
4. Aines, R.D. and Rossman, G.R., Mater in minerals? A peak in the infrared. Journal of Geophysical Research B9, 40594071, (1984).Google Scholar
5. Bartholomew, R.F., Butler, B.L., Hoover, H.L., Mu, C.K., Infrared spectra of a water-containing glass. Journal of the American Ceramic Society 63, 481485.Google Scholar
6. Stolper, E., Mater in silicate glasses: an infrared spectroscopic study. Contributions to Mineralogy and Petrology Bl, 117 (1982).CrossRefGoogle Scholar
7. Molters, D.R. and Verweij, H., The incorporation of water in silicate glasses. Physics and Chemistry of Glasses 22, 5561 (1981).Google Scholar
8. Mood, D.L., Rabinovich, E.M., Johnson, D.M. Jr., MacChesney, J.B., Vogel, E.M., Preparation of high-silica glasses from colloidal gels: III, Infrared spectrophotometric studies. Journal of the American Ceramic Society, 66, 693699 (1983).Google Scholar
9. Newman, S., Stolper, E.M., Epstein, S., Measurement of water in rhyolitic glasses: Calibration of an infrared spectroscopic technique. American Mineralogist, 71, 15271541 (1986).Google Scholar
10. Clark, R.N. and Roush, T.L., Reflectance spectroscopy: Quantitative analysis for remote sensing applications. Journal of Geophysical Research B9, 63296340, (1984).Google Scholar
11. Stolper, E., The speciation of water in silicate melts. Geochemica et Cosmochemica Acta 46, 26092620.CrossRefGoogle Scholar
12. Bates, J.K., Jardine, L.J., Steindler, M.J., The Hydration Process of Nuclear Waste Glass: An Interim Report. Argonne National Laboratory, Report ANL-82-ll (1982).Google Scholar
13. Diebold, F.E. and Bates, J.K., Glass-water vapor interaction. American Ceramic Society, Proceedings, 1986, in press.Google Scholar
14. Bates, J.K., unpublished.Google Scholar
15. Bazan, F., and Rego, J., Parametric Testing of a DWPF Glass. Lawrence Livermore National Laboratory, Report, UCRL 53606.Google Scholar
16. Wald, J.M., Fabrication and Characterization of MCC Approved Testing Material - ATM-1 Glass. Pacific Northwest Laboratory, Battelle Memorial Institute, Report PNL-5577-l, (1985).Google Scholar
17. Delany, J.M., Reaction of Topopah Spring Tuff with J-13 Mater: A Geochemical Modeling Approach Using the EQ3/6 Reaction Path Code. Lawrence Livermore National Laboratory, Report UCRL-53631, (1985).Google Scholar
18. Tsong, I.S.T., Houser, C.A., Tong, S.S.C., Depth profiles of interdiffusing species in hydrated glasses. Physics and Chemistry of Glasses 21, 197198, (1980).Google Scholar
19. Houser, C.A., Herman, J.S., Tsong, I.S.T., White, M.B., Lanford, W.A., Sodium-hydrogen interdiffusion in sodium silicate glasses. Journal of Non-Crystalline Solids 41, 8998 (1980).Google Scholar
20. Lanford, W.A., Davis, K., Lamarche, P., Groleau, R., Doremus, R.H., Hydration of soda-lime glass. Journal of Non-Crystalline Solids 33, 249266 (1979).Google Scholar
21. Doremus, R.H., Diffusion-controlled reaction of water with glass. Journal of Non-Crystalline Solids 55, 143147 (1983).Google Scholar
22. Nogami, M., and Tomazawa, M., Diffusion of water in high silica glasses at low temperature. Physics and Chemistry of Glasses 25, 8285 (1984).Google Scholar