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Applicatons of Hydration Thermodynamics to In-Situ Test Results

Published online by Cambridge University Press:  25 February 2011

M. J. Plodinec  and
G. G. Wicks
M. J. Plodinec
Affiliation:
Westinghouse Savannah River Co.Savannah River Technology CenterP. O. Box 616 Aiken, SC 29802
G. G. Wicks
Affiliation:
Westinghouse Savannah River Co.Savannah River Technology CenterP. O. Box 616 Aiken, SC 29802
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Abstract

An extremely important question for the eventual disposal of glass in natural environments is the relevance of laboratory testing of glass durability to the long-term performance of glass in geologic environments. The purpose of this study was to attempt to provide an empirical answer to that question, by applying the hydration thermodynamics approach (which has successfully been applied to laboratory tests of glass durability) to the results of longer-term testing in natural environments.

The results show that hydration thermodynamics is a useful tool for explaining the effects of glass composition observed in in-situ tests, in several environments. Thus, it appears to provide a link between laboratory tests of glass durability and the results of in-situ tests in natural environments. Perhaps the most important conclusion of this effort is that the in-situ test results emphasize the importance of control of chemical composition during glass production as a means of achieving a durable glass.

Type
Research Article
Information
MRS Online Proceedings Library (OPL) , Volume 333: Symposium V – Scientific Basis for Nuclear Waste Management XVII , 1993 , 145
Copyright
Copyright © Materials Research Society 1994

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References

REFERENCES

1 U. S. Department of Energy, Environmental Assessment - Waste Form Selection for SRP High-Level Waste, USDOE Document DOE/EA-0179, Washington, DC (1982).Google Scholar
2 Grover, J. R., “High-Level Waste Solidification - Why We Chose Glass,” Rad. Waste Management, 1, 112 (1982).Google Scholar
3 Wicks, G. G., “Nuclear Waste Glasses,” in Treatise on Materials Science and Technology, Glass IV, Tomozawa, M. and Doremus, R. H. (eds.), 57118 (1985).CrossRefGoogle Scholar
4 Plodinec, M. J., Wicks, G. G., and Bibler, N.E., An Assessment of Savannah River Boro-silicate Glass in die Repository Environment, USDOE Report DP-1629, Savannah River Laboratory, Aiken, SC (1982).CrossRefGoogle Scholar
5 Paul, A., “Chemical durability of glasses; a thermodynamic approach,” J. Materials Sci., 12, 2246–68 (1977).CrossRefGoogle Scholar
6 Newton, R. G., and A. Paul, “A new approach to predicting the durability of glasses from their chemical compositions,” Glass Technology, 21, 307–9 (1980).Google Scholar
7 Postles, R. L. and Brown, K. G., “The DWPF Product Composition Control System at Savannah River: Statistical Process Control Algorithm,” in Ceramic Transactions - Nuclear Waste Management IV, 23, Wicks, G. G., et al. (eds.), 559–68 (1991).Google Scholar
8 Hutson, N. D., Zamecnik, J. R., Ritter, J. A., and Carter, J. T., “Pilot Scale Processing of Simulated Savannah River Site High Level Radioactive Waste,” High Level Radioactive Waste and Spent Fuel Management, Proceedings of the 1991 Joint International Waste Management Conference, Slate, S. C., et al. (ed.), 1520 (1991).Google Scholar
9 Hutson, N. D., Jantzen, C. M., Beam, D. C., “A Pilot Scale Demonstration of the DWPF Process Control and Product Verification Strategy,” High Level Radioactive Waste Management, Proceedings of the Third International Conference, 525–32 (1992).Google Scholar
10 Andrews, M. K., Bibler, N. E., Jantzen, C. M., and Beam, D. C., “Initial Demonstration of the DWPF Vitrification Process and Product Control Strategy Using Actual Radioactive Waste,” in Ceramic Transactions - Nuclear Waste Management IV, 23, Wicks, G. G., et al. (eds.), 569–76 (1991).Google Scholar
11 Mendel, J. E. (ed.), Final Report of the Defense High-Level Waste Leaching Mechanisms Program, USDOE Report PNL-5157, Battelle-Pacific Northwest Laboratory, Richland, WA (1984).CrossRefGoogle Scholar
12 White, W. B., “Dissolution Mechanisms of Nuclear Glasses: A Critical Review,” Advances in Ceramics - Nuclear Waste Management, 20, Clark, D. E., et al. (eds.), 431–42 (1986).Google Scholar
13 Wicks, G. G., “Savannah River Waste Glass Performance,” Spectrum ’86, Proceedings of the American Nuclear Society’s Topical Meeting on Waste Management and Decontamination and Decommissioning, 896906 (1987).Google Scholar
14 Bibler, N. E., Glass Performance in a Geologic Setting, USDOE Report DP-MS-86-119, E. I. DuPont de Nemours, Inc., Savannah River Laboratory, Aiken SC 29808 (1986).Google Scholar
15 Bickford, D. F., Hrma, P., Bowan, B. W. III, “Control of Radioactive Waste Glass Melters: II, Residence Time and Melt Rate Limitations,” J. Am. Cer. Soc, 73, 2903–15 (1990).CrossRefGoogle Scholar
16 Plodinec, M. J., “Characterization of Savannah River Plant Waste Glass,” Waste Management 85, 1, Post, R. G. (ed.), 441–5 (1985).Google Scholar
17 Jantzen, C. M., Bickford, D. F., Karraker, D. G. and Wicks, G. G., “Time-temperature-transformation kinetics in SRL glass,” Advances in Ceramics - Nuclear Waste Management, 8, Ross, W. A. and Wicks, G. G. (eds.), 3038 (1984).Google Scholar
18 Bickford, D. F. and Jantzen, C. M., “Devitrification Behavior of SRL Defense Waste Glass,” Scientific Basis for Nuclear Waste Management, VII, McVay, G. L. (ed.), Elsevier, NY, 557–66, (1984).Google Scholar
19 Jantzen, C. M. and Bickford, D. F., “Leaching of Devitrified Glass Containing Simulated SRP Nuclear Waste,” Scientific Basis for Nuclear Waste Management, VII, Jantzen, C. M., et al. (ed), Materials Research Society, Pittsburgh, PA, 135–46 (1985).Google Scholar
20 Plodinec, M. J., Jantzen, C. M., Wicks, G. G., “Thermodynamic approach to prediction of the stability of proposed radwaste glasses,” Advances in Ceramics - Nuclear Waste Management, 8, Ross, W A. and Wicks, G. G. (eds.), 491–95 (1984).Google Scholar
21 Jantzen, C.M. and Plodinec, M. J., “Thermodynamic Model of Natural, Medieval and Nuclear Waste Glass Durability,” J. Non-Cryst Solids, 67, 207–23 (1984).CrossRefGoogle Scholar
22 Plodinec, M. J., Jantzen, C. M. and Wicks, G. G., “Stability of Radioactive Waste Glasses Assessed from Hydration Thermodynamics,” Scientific Basis for Nuclear Waste Management, VII, McVa, G. L.y (ed.), 755–62 (1985).Google Scholar
23 Jantzen, C. M., “Prediction of Nuclear Waste Glass Durability from Natural Analogs,” Advances in Ceramics - Nuclear Waste Management, 20, Clark, D. E., et al. (ed), 703712 (1986).Google Scholar
24 Jantzen, C. M., “Prediction of Glass Durability as a Function of Glass Composition and Test Conditions: Thermodynamics and Kinetics,” Proceedings - First International Conference on Advances in the Fusion of Glass, Bickford, D. F., et al. (ed.), American Ceramic Society, Westerville, OH, chapter 24 (1988).Google Scholar
25 Mendel, J. E. (compiler), Nuclear Waste Materials Handbook - Waste Form Test Methods, USDOE Report DOE/TIC 11400, Materials Characterization Center, Battelle Pacific Northwest Laboratory, Richland, WA (1981).Google Scholar
26 Jantzen, C. M., Bibler, N. E., Beam, D. C., Ramsey, W. G., Waters, B. J., Nuclear Waste Product Consistency Test (PCT) - Version 5.0, USDOE Report WSRC-TR-90-539, Revision 2, Savannah River Technology Center, Aiken, SC (1992).CrossRefGoogle Scholar
27 Bibler, N. E. and Jantzen, C. M., “The Product Consistency Test and its Role in the Waste Acceptance Process for DWPF Glass,” Waste Management 89, 1, Post, Roy G. (ed.), 743–9 (1989).Google Scholar
28 Jantzen, C. M., Bibler, N. E., “The product consistency test for the DWPF waste form,” Proceedings of the 2nd International Seminar on Radioactive Waste Products, Requirements for Waste Acceptance and Quality Control, Odoj, R., et al. (ed.), 609–22 (1990).Google Scholar
29 Zhu, B. F., Clark, D. E., Lodding, A. and Wicks, G. G., “Two-Year Leaching Behavior of Three SRTC Nuclear Waste Glasses in Granite,” Advances in Ceramics - Nuclear Waste Management, 20, Clark, D. E., et al. (eds.), 591600 (1986).Google Scholar
30 Zoitos, B. K., Lodding, A. R., and Wicks, G. G., “Correlation of Laboratory and Stripa Field Leaching Studies,” Scientific Basis for Nuclear Waste Management, XII, Lutze, W. and Ewing, R. C. (eds.), 145–51 (1989).Google Scholar
31 A., Lodding, et al. “SIMS Analysis of Leached Layers Formed on SRL Glasses During Burial,” Advances in Ceramics - Nuclear Waste Management, 20, Clark, D. E., et al. (eds.), 567–82 (1986).Google Scholar
32 Plodinec, M. J., “Controlling the durability of nuclear-waste glass,” in High Performance Glasses, Cable, M. and Parker, J. M. (eds), Blackie, Glasgow, 187209 (1992).Google Scholar
33 Wicks, G. G., Lodding, A. R., Macedo, P. B., Clark, D. E., Molecke, M. A., “MIIT; International In-Situ Testing of Simulated HLW Forms,” High-Level Radioactive Waste Management, 1, Proceedings of the International Topical Meeting, Shipler, D. B. (ed.), 443–50 (1990).Google Scholar
34 Wicks, G. G., Molecke, M. A., “WIPP/SRL In-situ Testing Program,” Advances in Ceramics - Nuclear Waste Management, 20, Clark, D. E., et al. (ed), 657–70 (1986).Google Scholar
35 Wicks, G. G., Molecke, M. A., “WIPP/SRL In-Situ Testing Program: MIΓΓ Update 1988,” Waste Management 88, 2, Post, Roy G. (ed.), 383–92 (1988).Google Scholar
36 Wicks, G. G., Molecke, M. A., “Overview of the Materials Interface Interactions Test (MITT); International In-Situ Testing of Waste Forms and Package Components,” presented at the Workshop on In Situ Testing of Radioactive Waste Forms and Engineered Barriers, Corsen-donk, Belgium, October 13–16, 1992, and published in the proceedings.Google Scholar