Subsurface mass transport affects the radioxenon signatures that are used to identify clandestine nuclear tests

Lowrey, Justin D.; Biegalski, Steven R; Osborne, Andrew G.; Deinert, Mark

doi:10.1029/2012gl053885

Cited by 33 publications

(16 citation statements)

References 19 publications

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“…Background concentrations of the gases in the subsurface and atmospheric boundary were assumed to be zero, although SF 6 , 3 He, and 133 Xe all have low background concentrations in air (Carrigan et al, 1996; Geller et al, 1997; Hebel, 2010). Our current work did not address other Xe isotopes or the contribution from 133 Xe precursors (radioiodine) to the original 133 Xe source term (Lowrey et al, 2013).…”

Section: Numerical Modelmentioning

confidence: 99%

“…Carrigan et al (1996) and Sun and Carrigan (2014) have developed numerical models for vadose zone transport of radionuclide gases from UNEs in fractured rock with barometric pumping. Double‐porosity modeling of subsurface transport of Xe isotopes from UNEs has also been used to show the effects of uncertain geologic properties on the fractionation of various Xe isotopes ( 133 Xe, metastable 133 Xe and 131 Xe, and 135 Xe) (Lowrey et al, 2013).…”

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confidence: 99%

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Uncertainty in Prediction of Radionuclide Gas Migration from Underground Nuclear Explosions

Jordan

Stauffer

Zyvoloski

et al. 2014

Vadose Zone Journal

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Underground nuclear explosions (UNEs) produce radionuclide gases that may seep to the surface over weeks to months. The objective of this research was to quantify the impact of uncertainties in hydrologic parameters (fracture aperture, matrix permeability, porosity, and saturation) and season of detonation on the timing of gas breakthrough. Numerical sensitivity analyses were performed, with barometric pumping providing the primary driving force for gas migration, for the case of a 1 kt UNE at 400-m depth of burial. Gas arrival time was most affected by matrix permeability and fracture aperture. Gases having higher diffusivity were more sensitive to uncertainty in the rock properties. The effect of seasonality in the barometric pressure forcing was found to be important, with detonations in March the least likely to be detectable based on barometric data for Rainier Mesa, Nevada. Monte Carlo realizations were performed with all four parameters varying simultaneously to determine their interrelated effects. The Monte Carlo method was also used to predict the window of opportunity for 133 Xe detection from a 1 kt UNE at Rainier Mesa, with and without matching the model to SF 6 and 3 He data from the 1993 Non-Proliferation Experiment. Results from the data-blind Monte Carlo simulations were similar but were biased toward earlier arrival time and less likely to show detectable 133 Xe. The estimated timing of gas arrival may be used to deploy personnel and equipment to the site of a suspected UNE, if allowed under the terms of the Comprehensive Nuclear Test-Ban Treaty.

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Section: Numerical Modelmentioning

confidence: 99%

mentioning

confidence: 99%

Uncertainty in Prediction of Radionuclide Gas Migration from Underground Nuclear Explosions

Jordan

Stauffer

Zyvoloski

et al. 2014

Vadose Zone Journal

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“…Measurement of radioxenon during an OSI is heavily dependent on underground transport processes and the geology through which transport occurs (Carrigan et al, 1996;Carrigan and Sun, 2014;Lowrey et al, 2013Lowrey et al, , 2012.While transport in homogenous media may be dominated by diffusion at small scales, in fractured geologies barometric pumping is predicted to dominate the bulk movement of air (Nilson et al, 1991). Barometric pumping involves changes in atmospheric pressure acting to impress or withdraw gas from the subsurface, with it generally resulting in an increase in the rate of vertical mixing of air in the subsurface (Carrigan and Sun, 2011;Lowrey, 2013).…”

Section: Imprintingmentioning

confidence: 99%

Detection in subsurface air of radioxenon released from medical isotope production

Johnson

Biegalski

Haas

et al. 2017

Journal of Environmental Radioactivity

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In order to better understand potential backgrounds of Comprehensive-Nuclear Test-Ban Treaty on-site inspection relevant gases, a sampling campaign was performed near Canadian Nuclear Laboratories in the Ottawa River Valley, a major source of environmental radioxenon. First of their kind measurements of atmospheric radioxenon imprinted into the shallow subsurface from an atmospheric pressure driven force were made using current on-site inspection techniques. Both atmospheric and subsurface gas samples were measured and analyzed to determine radioxenon concentrations. These measurements indicate that under specific sampling conditions, on the order of ten percent of the atmospheric radioxenon concentration may be measured via subsurface sampling.

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“…Immediately following the blast, the initial heat and pressure drives bulk movement of explosion gases. In the days and months following the blast, longer-term gas diffusion and weatherdriven advection take over in a process called barometric pumping to more slowly drive noble gases to the surface [2,3]. The Noble Gas Migration Experiment (NGME) reported here focused on a typical OSI scenario in which the primary mode of transport of the noble gases to the surface was by barometric pumping.…”

Section: Introductionmentioning

confidence: 99%

Noble gas migration experiment to support the detection of underground nuclear explosions

Olsen

Kirkham

Woods

et al. 2015

J Radioanal Nucl Chem

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A Noble Gas Migration Experiment injected 127 Xe, 37 Ar, and sulfur hexafluoride into a former underground nuclear explosion shot cavity. These tracer gases were allowed to migrate from the cavity to near-surface and surface sampling locations and were detected in soil gas samples collected using various on-site inspection sampling approaches. Based on this experiment we came to the following conclusions: (1) SF 6 was enriched in all of the samples relative to both 37 Ar and 127 Xe. (2) There were no significant differences in the 127 Xe to 37 Ar ratio in the samples relative to the ratio injected into the cavity. (3) The migratory behavior of the chemical and radiotracers did not fit typical diffusion modeling scenarios.

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Subsurface mass transport affects the radioxenon signatures that are used to identify clandestine nuclear tests

Cited by 33 publications

References 19 publications

Uncertainty in Prediction of Radionuclide Gas Migration from Underground Nuclear Explosions

Uncertainty in Prediction of Radionuclide Gas Migration from Underground Nuclear Explosions

Detection in subsurface air of radioxenon released from medical isotope production

Noble gas migration experiment to support the detection of underground nuclear explosions

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