Lunde R. Reed scite author profile

Environmental context. The production of nuclear materials has generated a very large amount of highly radioactive wastes that need to be disposed of in a manner that will keep them from posing a danger for millions of years until the radioactivity decays. The process being considered for this daunting task is to contain the wastes in glass. Although studies with ancient and natural glass suggest the weathering of glass is slow, experiments are being conducted to determine the impact of this material on the natural environment and attempt to predict its long-term behaviour. The present paper briefly discusses three models that are being considered for implementing this process and the one that appears to hold the most promise. Abstract. Single-pass flow-through experiments were conducted with aluminoborosilicate waste glasses to evaluate how changes in solution composition affect the dissolution rate (r) at 40°C and pH (23°C) = 9.0. The three prototypic low-activity waste (LAW) glasses, LAWE-1A, -95A and -290A, used in these experiments span a wide range covering the expected processing composition of candidate immobilised low-activity waste (ILAW) glasses. Results suggest incongruent release of Al, B, Na, and Si at low flow-rate (q) to sample surface area (S), in units of (m s–1), (log10(q/S) < –8.9) whereas congruent release is observed at high q/S (log10(q/S) > –7.9). Dissolution rates increase from log10(q/S) ≈ –9.3 to –8.0 and then become constant at log10(q/S) > –7.9. Forward (maximum) dissolution rates, based on B release, are the same irrespective of glass composition, evident by the dissolution rates being within the experimental error of one another (r1A = 0.0301 ± 0.0153 g m–2 day–1, r95A = 0.0248 ± 0.0125 g m–2 day–1, and r290A = 0.0389 ± 0.0197 g m–2 day–1). The results also illustrate that as the activity of SiO2(aq) increases, the rate of glass dissolution decreases to a residual rate. The pseudo-equilibrium constant, Kg, (log10(Kg) = –3.7) predicted with these results is slightly lower than the K for chalcedony (log10(K) = –3.48) at 40°C. Finally, these results support the use of a chemical affinity-based rate law to describe glass dissolution as a function of solution composition.

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Laboratory Testing of Bulk Vitrified Low-Activity Waste Forms to Support the 2005 Integrated Disposal Facility Performance Assessment

Pierce¹,

McGrail²,

Bagaasen³

et al. 2005

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SummaryThe Hanford Site in southeastern Washington State has been used extensively to produce nuclear materials for the U. S. strategic defense arsenal by the U. S. Department of Energy (DOE). A large inventory of radioactive and mixed waste has accumulated in 177 single-and double-shell tanks. Waste recovered from the tanks will be pre-treated to separate the low-activity fraction from the high-level and transuranic wastes. The low-activity fraction will be among the largest volumes of radioactive waste within the DOE complex and is one of the largest inventories of long-lived radionuclides planned for disposal in a low-level waste facility. Currently, the DOE Office of River Protection (ORP) is evaluating several options for immobilization of low-activity tank wastes for eventual disposal in a shallow subsurface facility at the Hanford Site. A significant portion of the waste will be converted into immobilized low-activity waste (ILAW) glass with a conventional Joule-heated ceramic melter. In addition to ILAW glass, DOE is considering a supplemental treatment technology; bulk vitrification (BV), to treat a portion of the low-activity waste (LAW). The use of a supplemental treatment technology is expected to accelerate the overall cleanup mission at the Hanford site by at least 35 years. CH2M Hill Hanford Group, Inc. A critical component of the development and testing strategy will be to provide estimates of radionuclide release rates from the engineered portion of the disposal facilities (source term). These data will be used for Subsurface Transport Over Reactive Multi-phases (STORM) simulations of the BV waste package. Documented in this report are data related to 1) kinetic rate law parameters for glass and refractory dissolution, 2) sodium (Na + )-hydrogen (H + ) ion exchange rate, 3) chemical reaction network of secondary phases that form in accelerated weathering tests, and 4) thermodynamic equilibrium constants assigned to these secondary phases for BV vitrified product. The kinetic rate law and Na + -H + ion exchange rate were determined from single-pass flow-through (SPFT) experiments. Product consistency (PCT) tests were used for accelerated weathering or aging of the glasses to determine a chemical reaction network of secondary phases that form. The majority of the thermodynamic data used in this data package were extracted from the thermodynamic database package provided with the geochemical code EQ3/6, version 8.0.Results from SPFT tests suggest that rate law parameters derived for BV glasses are comparable to those determined for WTP glass formulations. SPFT tests also were used to calculate a bounding release rate for the mullite castable refractory block (CRB). The presence of multiple mineral phases in and the uncertainty regarding the true reactive surface area of the CRB may have a significant effect on the reported rates. Therefore, we recommend that rate law parameters be developed for the pure mineral phases identified in the CRB. These results should be combined with literature values to...

show abstract

Laboratory Testing of Bulk Vitrified Low-Activity Waste Forms to Support the 2005 Integrated Disposal Facility Performance Assessment

Pierce¹,

McGrail²,

Bagaasen³

et al. 2006

View full text Add to dashboard Cite

SummaryThe Hanford Site in southeastern Washington State has been used extensively to produce nuclear materials for the U. S. strategic defense arsenal by the U. S. Department of Energy (DOE). A large inventory of radioactive and mixed waste has accumulated in 177 single-and double-shell tanks. Waste recovered from the tanks will be pre-treated to separate the low-activity fraction from the high-level and transuranic wastes. The low-activity fraction will be among the largest volumes of radioactive waste within the DOE complex and is one of the largest inventories of long-lived radionuclides planned for disposal in a low-level waste facility. Currently, the DOE Office of River Protection (ORP) is evaluating several options for immobilization of low-activity tank wastes for eventual disposal in a shallow subsurface facility at the Hanford Site. A significant portion of the waste will be converted into immobilized low-activity waste (ILAW) glass with a conventional Joule-heated ceramic melter. In addition to ILAW glass, DOE is considering a supplemental treatment technology; bulk vitrification (BV), to treat a portion of the low-activity waste (LAW). The use of a supplemental treatment technology is expected to accelerate the overall cleanup mission at the Hanford site by at least 35 years. CH2M Hill Hanford Group, Inc. A critical component of the development and testing strategy will be to provide estimates of radionuclide release rates from the engineered portion of the disposal facilities (source term). These data will be used for Subsurface Transport Over Reactive Multi-phases (STORM) simulations of the BV waste package. Documented in this report are data related to 1) kinetic rate law parameters for glass and refractory dissolution, 2) sodium (Na + )-hydrogen (H + ) ion exchange rate, 3) chemical reaction network of secondary phases that form in accelerated weathering tests, and 4) thermodynamic equilibrium constants assigned to these secondary phases for BV vitrified product. The kinetic rate law and Na + -H + ion exchange rate were determined from single-pass flow-through (SPFT) experiments. Product consistency (PCT) tests were used for accelerated weathering or aging of the glasses to determine a chemical reaction network of secondary phases that form. The majority of the thermodynamic data used in this data package were extracted from the thermodynamic database package provided with the geochemical code EQ3/6, version 8.0.Results from SPFT tests suggest that rate law parameters derived for BV glasses are comparable to those determined for WTP glass formulations. SPFT tests also were used to calculate a bounding release rate for the mullite castable refractory block (CRB). The presence of multiple mineral phases in and the uncertainty regarding the true reactive surface area of the CRB may have a significant effect on the reported rates. Therefore, we recommend that rate law parameters be developed for the pure mineral phases identified in the CRB. These results should be combined with literature values to...

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Lunde R. Reed

Experimental determination of the effect of the ratio of B/Al on glass dissolution along the nepheline (NaAlSiO4)–malinkoite (NaBSiO4) join

Waste Form Release Data Package for the 2005 Integrated Disposal Facility Performance Assessment

Aluminoborosilicate waste glass dissolution under alkaline conditions at 40°C: implications for a chemical affinity-based rate equation

Laboratory Testing of Bulk Vitrified Low-Activity Waste Forms to Support the 2005 Integrated Disposal Facility Performance Assessment

Laboratory Testing of Bulk Vitrified Low-Activity Waste Forms to Support the 2005 Integrated Disposal Facility Performance Assessment

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