Reactions during melting of low-activity waste glasses and their effects on the retention of rhenium as a surrogate for technetium-99

Jin, Tongan; Kim, Dong-Sang; Tucker, Abigail E.; Schweiger, Michael J.; Kruger, Albert A.

doi:10.1016/j.jnoncrysol.2015.05.018

Cited by 45 publications

(49 citation statements)

References 37 publications

(52 reference statements)

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“…The chemical form of the extracted boron in the salt phase is unknown; it could be borate ions such as

{BO}_{2}^{-}

{normalB}_{4} {normalO}_{7}^{2 -}

, etc.

{BO}_{2}^{-}

was more likely based on the charge balance calculation similar to Jin et al; if

{normalB}_{4} {normalO}_{7}^{2 -}

is used instead, the mole ratio of total positive charge to negative charge would increase slightly to 1.04‐1.10. Uncertainties associated with the chemical analyses are estimated based on duplicate tests.…”

Section: Resultsmentioning

confidence: 99%

A crucible salt saturation method for determining sulfur solubility in glass melt

Jin

Kim

et al. 2018

Int J of Appl Glass Sci

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Experiments were conducted to determine sulfur solubility in Hanford low‐activity waste (LAW) glass melts by a sulfur saturation method. Sulfur‐incorporated glass melts were prepared by salt saturation and bubbling methods. The salt saturation method was performed by mixing crushed premelted baseline glasses with an excess amount of Na2SO4 prior to melting the mixture at 1150°C for 1 hour. The bubbling method involved bubbling the glass melt at 1150°C in a Pt crucible with an SO2/O2/N2 gas mix to equilibrate the melt at a known pressure of SO3. Preliminary results suggested that performing 1 cycle of mixing and melting was not sufficient to saturate the glass. The bubbling method successfully incorporated sulfur into the glass but caused significant losses of sodium from the melt. In order to saturate the glass melt with sulfate without causing noticeable sodium loss, a modified crucible salt saturation method was developed by repeating the mixing and melting of the glass and salt mixture. For all 3 representative LAW glasses tested in this study, it was found that after 3 mixing and melting cycles, the sulfur concentration reaches a plateau, indicating reasonable sulfur saturation.

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“…The chemical form of the extracted boron in the salt phase is unknown; it could be borate ions such as

{BO}_{2}^{-}

{normalB}_{4} {normalO}_{7}^{2 -}

, etc.

{BO}_{2}^{-}

was more likely based on the charge balance calculation similar to Jin et al; if

{normalB}_{4} {normalO}_{7}^{2 -}

Section: Resultsmentioning

confidence: 99%

A crucible salt saturation method for determining sulfur solubility in glass melt

Jin

Kim

et al. 2018

Int J of Appl Glass Sci

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“…The simple inexpensive volume expulsion test is a handy technique that can minimize the effort needed for execution of melter experiments. Experiments performed with pellets from feeds other than A0, a high‐alumina feed chosen for this work because of the availability of data needed for density and porosity evaluation, show that volume changes in response to heating can widely differ depending on the gas evolution rate and melt formation rate as functions of temperature . This diversity of responses may challenge the formulation of ρ b ( T ) and ϕ( T ) approximation functions that are essential for cold cap modeling.…”

Section: Discussionmentioning

confidence: 99%

“…Experiments performed with pellets from feeds other than A0, a high-alumina feed chosen for this work because of the availability of data needed for density and porosity evaluation, show that volume changes in response to heating can widely differ depending on the gas evolution rate and melt formation rate as functions of temperature. [30][31][32][33] This diversity of responses may challenge the formulation of q b (T) and /(T) approximation functions that are essential for cold cap modeling. These functions will also be useful for quantifying the effects of feed makeup variations, such as quartz particle size or the chemical and mineralogical form of the feed additives, on the feed foaming extent and, hence, on the impact of feed formulation on cold cap behavior, including the rate of melting.…”

Section: January 2016 Porosity During Vitrificationmentioning

confidence: 99%

A Method for Determining Bulk Density, Material Density, and Porosity of Melter Feed During Nuclear Waste Vitrification

Hilliard

Hrma

2015

J. Am. Ceram. Soc.

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Glassmelting efficiency largely depends on heat transfer to reacting glass batch (melter feed), which in turn is influenced by the bulk density (ρb) and porosity (ϕ) of the reacting feed as functions of temperature (T). Neither ρb(T) nor ϕ(T) functions are readily accessible from direct measurements. For the determination of ρb, we monitored the profile area of heated feed pellets and calculated the pellet volume using numerical integration. For the determination of ϕ, we measured the material density of feeds quenched at various stages of conversion via pycnometry and then computed the feed density at heat‐treatment temperature using thermal expansion values of basic feed constituents.

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“…To determine the rheological properties of the slurry feed, water was slowly evaporated from the initial slurry while aliquots of ~5 mL and ~40 mL were sampled at regular intervals. The 5 mL aliquots were used to measure the water content ( w p ) by determining weight loss in a 24‐hour period at 105°C . The 40 mL aliquot was used to perform rheometry in an Anton Paar M301 rheometer at 80°C.…”

Section: Methodsmentioning

confidence: 99%

Rheology of simulated radioactive waste slurry and cold cap during vitrification

et al. 2018

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During the vitrification of radioactive waste in a Joule‐heated melter, aqueous melter feed slurry forms a cold cap, a reacting and melting material, which floats on the surface of the molten glass. The rheological behavior of the feed affects cold cap formation and shape, and is vital for modeling the feed‐to‐melt conversion process. We used slurry feed simulant and fast‐dried slurry solids representing the cold cap to investigate the rheological behavior of the feed as it transforms into glass. Both low‐temperature and high‐temperature rheometry were performed and a new scheme was applied to estimate the feed viscosity. This study shows that the conversion advances in four sequential stages that form distinct regions in the cold cap: (i) a fast‐spreading boiling slurry from which water evaporates, (ii) a porous solid region (viscosity > 108 Pa s) containing reacting solids and molten salts, (iii) a plastic region in which glass‐forming melt connects the refractory solids (~108 to ~106 Pa s), and (iv) a viscous foam layer in which the viscosity drops from ~105 to ~101 Pa s. The implications for the mathematical modeling of the cold cap are discussed.

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Reactions during melting of low-activity waste glasses and their effects on the retention of rhenium as a surrogate for technetium-99

Cited by 45 publications

References 37 publications

A crucible salt saturation method for determining sulfur solubility in glass melt

A crucible salt saturation method for determining sulfur solubility in glass melt

A Method for Determining Bulk Density, Material Density, and Porosity of Melter Feed During Nuclear Waste Vitrification

Rheology of simulated radioactive waste slurry and cold cap during vitrification

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