The Second Las Cruces Trench Experiment: Experimental Results and Two‐Dimensional Flow Predictions

Hills, R. G.; Wierenga, P. J.; Hudson, David; Kirkland, Michael

doi:10.1029/91wr01538

Cited by 64 publications

(38 citation statements)

References 12 publications

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“…Important vadose zone transport processes have been identified in the few large-scale transport studies conducted internationally during the last decade. Studies include transport tests in the United States at Las Cruces, New Mexico (Wierenga et al 1990;Hills et al 1991;Rockhold et al 1996); at Idaho National Engineering Laboratory in Idaho Falls, Idaho (Wood and Norrell 1996); and at Maricopa, Arizona (Young et al 1996). Studies outside of the United States include studies in Canada (Kachanoski et al 1990;van Wesenbeeck and Kachanoski 1994) and in Europe (Schulin et al 1987;Hammel and Roth 1998).…”

Section: Technical Backgroundmentioning

confidence: 99%

Vadose Zone Transport Field Study: Summary Report

Ward¹,

Conrad²,

Daily³

et al. 2006

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SummaryA series of field studies were conducted at the Hanford Site, near Richland, Washington, from FY 2000 through FY 2003 at two different locations to develop data sets to test models of flow and transport in the vadose zone. The field studies were also done to investigate advanced monitoring techniques for evaluating flow-and-transport mechanisms and delineating contaminant plumes in the vadose zone at the Hanford Site. The studies were conducted as part of the Groundwater/Vadose Zone Integration Project Science and Technology Project, now known as the Remediation and Closure Science Project, managed by the Pacific Northwest National Laboratory (PNNL) and supported by the U.S. Department of Energy, Richland Operations Office. This report summarizes the key findings from the field studies and demonstrates how data collected from these studies are being used to improve conceptual models and develop numerical models of flow and transport in Hanford's vadose zone. Results from the field studies and associated analysis have appeared in more than 46 publications generated over the past 4 years. These publications include test plans and status reports in addition to numerous technical notes and papers.Two major field campaigns were performed, one at a well injection test site and a second at a clastic dike test site. Both field studies have resulted in field-scale transport parameters for Hanford conditions, which are useful for improving predictions of subsurface flow and transport at the Hanford Site. In addition, advanced geophysical methods, including high resolution electrical resistivity measurements, were successfully tested and are now being deployed at Hanford for subsurface investigations and tank retrieval detection. The most useful information gained from these studies has been a better understanding of flow and transport in the vadose zone, and this has been specifically related to the impact of small-scale stratigraphic features (e.g., sediment layering) on water flow and contaminant transport. Conceptual models have been developed that take into account the lateral spreading of water and contaminants observed in the field studies. Numerical models of unsaturated flow and transport have been revised to account for lateral spreading of subsurface contaminant plumes.The key results from these studies include: 1) Greater understanding of the complexity of plume migration in the vadose zone at Hanford. Finescale geologic heterogeneities, including grain fabric and lamination, were observed to have a strong effect on the large-scale behavior of contaminant plumes, primarily through increased lateral spreading resulting from anisotropy.2) Observations of anion exclusion in Hanford sediments. Anion exclusion is a mechanism by which negatively charged ions are repelled from the surfaces of negatively charged soil particles, thereby increasing their velocity. Thus, the travel time of ions like pertechnetate, the stable form of 99 Tc found in oxidized environments, may decrease over that of unsaturated water f...

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Section: Technical Backgroundmentioning

confidence: 99%

Vadose Zone Transport Field Study: Summary Report

Ward¹,

Conrad²,

Daily³

et al. 2006

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“…Berino loamy fine sand [Hills et al, 1991] of the system, the decrease in the relative head is nearly linear. For the largest a(H 1 À H 2 ) = 1, there is an increase in the normalized head above the 1:1 line as x/L increases and then a return back to the 1:1 line at the outflow end of the system (x/L = 1).…”

Section: Examples and Calculationsmentioning

confidence: 79%

“…Table 1. The van Genuchten model parameters are from Hills et al [1991] and the equivalent Gardner alpha parameter was computed by numerical integration of the van Genuchten hydraulic conductivity function between h = 0 and h = À1 m:…”

Section: Examples and Calculationsmentioning

confidence: 99%

Steady state lateral water flow through unsaturated soil layers

Warrick

Hinnell

Ferré

et al. 2008

Water Resources Research

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The effects of gravity on flow through variably saturated soil layers are investigated quantitatively using two new analytical solutions and a numerical model. In all cases, steady state flow occurs laterally through a tilted, rectangular layer of soil with a constant hydraulic head on either end. The first solution is for gravity‐driven flow through a tilted layer with sublayering parallel to the slope. As intuitively suggested by earlier investigators, flow occurs parallel to the floor of the layer and the pressure head is a simple function of the normal distance from the floor of the layer. The second analytical solution is for a tilted soil layer described by a Gardner soil model with both gravity and pressure head gradients. Flow velocities remain parallel to the layer floor, which is confirmed by numerical simulations. This is in contrast with chosen non‐Gardner examples for which the flow does not necessarily remain parallel to the floor.

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“…First, the simpler single-continuum model seems inadequate to model the observed VOC concentration data, and second, the last decade of research has shown that, with a few exceptions (e.g., Wierenga, 1991;Hills et al, 1991), preferential flow is pervasive in the vadose zone (Kung, 1990a,b;Ghodrati and Jury, 1990;1992;Li and Ghodrati, 1994;Flury et al, 1994Flury et al, , 1995McCord et al, 1997).…”

Section: Conceptual Models For Subsurface Flow and Transportmentioning

confidence: 99%