Radionuclide Partitioning in an Underground Nuclear Test Cavity

Rose, Thomas; Hu, Qinhong; Zhao, Pihong; Conrado, C.L.; Dickerson, Robert P.; Eaton, G. F.; Kersting, Annie B.; Moran, J. E.; Nimz, G. J.; Powell, Brian A.; Ramon, E; Ryerson, Frederick J.; Williams, Ross W.; Wooddy, P. T.; Zavarin, Mavrik

doi:10.2172/1019060

Cited by 4 publications

(11 citation statements)

References 62 publications

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“…Two 55-gallon drums of water were collected from borehole U-19adPS#1a soon after it was drilled into the Chancellor nuclear test cavity in 2004. Chancellor water was used for this study because it has relatively high colloid concentrations and very high 239/240 Pu concentrations compared to other NNSS cavity waters, and most of the Pu is associated with the colloids (Reimus et al, 2006, Appendix C;Rose et al, 2011). It is the only cavity water we are aware of in which the alpha activity is dominated by 239/240 Pu rather than by uranium isotopes.…”

Section: Chancellor Cavity Watermentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

“…We chose to focus on colloids from the Chancellor nuclear test cavity at the NNSS because this cavity water has unusually high concentrations of 137 Cs and 239/240 Pu compared to other NNSS cavity waters, and both of these radionuclides were already known to be quite strongly associated with colloids in the water (Reimus et al, 2006;Rose et al, 2011). The high radionuclide concentrations in the Chancellor cavity water may be related to a hydrologic isolation of the cavity that is also inferred from high residual temperatures and more reducing redox conditions than is typical of cavity waters at the NNSS (Rose et al, 2011). While we recognize that such hydrologic conditions would tend to limit colloid and radionuclide transport out of the cavity, thus reducing the potential relevance of experimental results obtained using Chancellor water, there appears to be nothing unique about the properties of Chancellor water colloids relative to other NNSS cavity waters, and it is quite possible that similar radionuclide concentrations and temperatures existed in more hydrologically-connected cavities at early times after nuclear detonation.…”

Section: Introductionmentioning

confidence: 99%

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Chancellor Water Colloids: Characterization and Radionuclide Associated Transport

Reimus¹,

Boukhalfa²

2014

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Column transport experiments were conducted in which water from the Chancellor nuclear test cavity was tranported through crushed volcanic tuff from Pahute Mesa. In one experiment, the cavity water was spiked with solute 137 Cs, and in another it was spiked with 239/240 Pu(IV) nanocolloids. A third column experiment was conducted with no radionuclide spike at all, although the 137 Cs concentrations in the water were still high enough to quantify in the column effluent. The radionuclides strongly partitioned to natural colloids present in the water, which were characterized for size distribution, mass concentration, zeta potential/surface charge, critical coagulation concentration, and qualitative mineralogy. In the spiked water experiments, the unanalyzed portion of the high-concentration column effluent samples were combined and re-injected into the respective columns as a second pulse. This procedure was repeated again for a third injection. Measurable filtration of the colloids was observed after each initial injection of the Chancellor water into the columns, but the subsequent injections (spiked water experiments only) exhibited no apparent filtration, suggesting that the colloids that remained mobile after relatively short transport distances were more resistant to filtration than the initial population of colloids. It was also observed that while significant desorption of 137 Cs from the colloids occurred after the first injection in both the spiked and unspiked waters, subsequent injections of the spiked water exhibited much less 137 Cs desorption (much greater 137 Cs colloid-associated transport). This result suggests that the 137 Cs that remained associated with colloids during the first injection represented a fraction that was more strongly adsorbed to the mobile colloids than the initial 137 Cs associated with the colloids. A greater amount of the 239/240 Pu desorbed from the colloids during the second column injection compared to the first injection, but then desorption decreased significantly in the third injection. This result suggests that the Pu(IV) nanocolloids probably at least partially dissolved during and after the first injection, resulting in enhanced desorption from the colloids during the second injection, but by the third injection the Pu started following the same trend that was observed for 137 Cs. The experiments suggest a transport scale dependence in which mobile colloids and colloid-associated radionuclides observed at downstream points along a flow path have a greater tendency to remain mobile along the flow path than colloids and radionuclides observed at upstream points. This type of scale dependence may help explain observations of colloid-facilitated Pu transport over distances of up to 2 km at Pahute Mesa.

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Section: Chancellor Cavity Watermentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Chancellor Water Colloids: Characterization and Radionuclide Associated Transport

Reimus¹,

Boukhalfa²

2014

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“…These concepts are discussed more thoroughly in IAEA (1998a, b, c), the original YF HST reports (Carle et al, 2008;McNab;2008;Pawloski, et al, 2008;and Tompson, et al, 2008), in the more recent studies of Rose et al (2011) and Tompson et al (2011), and in Section C.3.…”

Section: C24 Physical Partitioning and Spatial Distribution Of Thementioning

confidence: 99%

“…Partitioning was based on IAEA (1998a) recommendations and adjusted, when appropriate, based on direct evidence from the NNSS. The direct evidence came primarily from two sources: The Rainier Mesa HST analysis (Tompson, et al, 2011) and the summary of radionuclide partitioning based on sampling efforts at the Chancellor site (Rose et al, 2011). Uncertainty in the glass partitioning is not well known.…”

Section: Figure C3 Comparison Of (A) 3h and (B) 90sr Rsts At T0 Formentioning

confidence: 99%

Appendix C: Hydrologic Source Term Screening and Distribution

Tompson¹,

Zavarin²

2012

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Colloid-Facilitated Transport of Plutonium at the Nevada Test Site, NV, USA

Kersting

Zavarin

2011

Actinide Nanoparticle Research

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Increasing observations of subsurface actinide transport has reinforced the need for a basic geochemical and hydrologic understanding of how these contaminants are transported in groundwater. At the Nevada Test Site, NV, USA, low-levels of plutonium have been shown to migrate on the scale of kilometers. At all but one sampling location the Pu is associated with the colloidal fraction (<1 mm) consisting predominantly of clays and zeolites. The majority of the Pu ($70%) is associated with the smallest nanoparticle (e.g., colloid) size fraction of 10-100 nm and in one case was identified as associated with a clay colloid. At one unique sampling site, Pu is predominantly associated with dissolved organic matter. Monitoring at over 20 contaminated groundwater sites at the NTS suggests that low-levels of Pu can be mobilized either via colloid-facilitated transport in fractured rock or as a result of aqueous Pu stabilization by anthropogenic levels of dissolved organic matter. Nevertheless, activities above the EPA's Maximum Contaminant Level (MCL) for alpha-emitting radionuclides (15 pCi/L, 0.56 Bq/L) have been measured at only two locations at the NTS.

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Radionuclide Partitioning in an Underground Nuclear Test Cavity

Cited by 4 publications

References 62 publications

Chancellor Water Colloids: Characterization and Radionuclide Associated Transport

Chancellor Water Colloids: Characterization and Radionuclide Associated Transport

Appendix C: Hydrologic Source Term Screening and Distribution

Colloid-Facilitated Transport of Plutonium at the Nevada Test Site, NV, USA

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