Three-Dimensional Groundwater Models of the 300 Area at the Hanford Site, Washington State

Williams, Mark; Rockhold, Mark; Thorne, Paul D.; Chen, Yousu

doi:10.2172/969184

Cited by 43 publications

(91 citation statements)

References 36 publications

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“…The Hanford Formation gravel and sand, deposited by glacial outburst floods at the end of the Pleistocene (Bjornstad, 2007), has a high average hydraulic conductivity at ∼ 3100 m day −1 (Williams et al, 2008). The fluvial deposits of the Ringold Formation have much lower hydraulic conductivity than those in the Hanford Formation but are still relatively conductive at 36 m day −1 (Williams et al, 2008). Fine-grained lacustrine Ringold silt has a much lower estimated hydraulic conductivity of 1 m day −1 .…”

Section: The Hanford Site and The 300 Areamentioning

confidence: 99%

“…Fine-grained lacustrine Ringold silt has a much lower estimated hydraulic conductivity of 1 m day −1 . The hydraulic conductivity of recent alluvium lining the river channel is low relative to the Hanford Formation, which tends to dampen the response of water table elevation in wells near the river when changes occur in river stage (Hammond et al, 2011;Williams et al, 2008). Overall, the Columbia River through the Hanford Reach is a prime example of a hyporheic corridor with an extensive floodplain aquifer.…”

Section: The Hanford Site and The 300 Areamentioning

confidence: 99%

“…Coupled with dynamic river stage variations, the resulting system is characterized by stage-driven intrusion and retreat of river water into the adjacent unconfined aquifer system. During high-stage spring runoff events, river water has been detected in monitoring wells nearly 400 m from the shoreline (Williams et al, 2008). During baseline, low-stage conditions (OctoberFebruary), the Columbia River is a gaining stream, and the aquifer pore space is occupied by groundwater.…”

Section: The Hanford Site and The 300 Areamentioning

confidence: 99%

“…Note that only the soil moisture and soil hydraulic properties within the top 3.8 m are transferred from PFLOTRAN to CLM4.5 to allow simulations of infiltration, evaporation, and transpiration in the next time step, as the CLM4.5 subsurface domain is limited to 3.8 m and cannot currently be easily modified. The hydrogeological properties of the Hanford and Ringold materials (Table 2) were taken from Williams et al (2008). The unsaturated hydraulic conductivity in PFLTORAN simulations was computed using the Van Genuchten water retention function (van Genuchten, 1980) and the Burdine permeability relationship (Burdine, 1953).…”

Section: Model Configuration Numerical Experiments and Analysesmentioning

confidence: 99%

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Coupling a three-dimensional subsurface flow and transport model with a land surface model to simulate stream–aquifer–land interactions (CP v1.0)

et al. 2017

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Abstract. A fully coupled three-dimensional surface and subsurface land model is developed and applied to a site along the Columbia River to simulate three-way interactions among river water, groundwater, and land surface processes. The model features the coupling of the Community Land Model version 4.5 (CLM4.5) and a massively parallel multiphysics reactive transport model (PFLOTRAN). The coupled model, named CP v1.0, is applied to a 400 m × 400 m study domain instrumented with groundwater monitoring wells along the Columbia River shoreline. CP v1.0 simulations are performed at three spatial resolutions (i.e., 2, 10, and 20 m) over a 5-year period to evaluate the impact of hydroclimatic conditions and spatial resolution on simulated variables. Results show that the coupled model is capable of simulating groundwater-river-water interactions driven by river stage variability along managed river reaches, which are of global significance as a result of over 30 000 dams constructed worldwide during the past half-century. Our numerical experiments suggest that the land-surface energy partitioning is strongly modulated by groundwater-river-water interactions through expanding the periodically inundated fraction of the riparian zone, and enhancing moisture availability in the vadose zone via capillary rise in response to the river stage change. Meanwhile, CLM4.5 fails to capture the key hydrologic process (i.e., groundwater-river-water exchange) at the site, and consequently simulates drastically different water and energy budgets. Furthermore, spatial resolution is found to significantly impact the accuracy of estimated the mass exchange rates at the boundaries of the aquifer, and it becomes critical when surface and subsurface become more tightly coupled with groundwater table within 6 to 7 meters below the surface. Inclusion of lateral subsurface flow influenced both the surface energy budget and subsurface transport processes as a result of river-water intrusion into the subsurface in response to an elevated river stage that increased soil moisture for evapotranspiration and suppressed available energy for sensible heat in the warm season. The coupled model developed in this study can be used for improving mechanistic understanding of ecosystem functioning and biogeochemical cycling along river corridors under historical and future hydroclimatic changes. The dataset presented in this study can also serve as a good benchmarking case for testing other integrated models.

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Section: The Hanford Site and The 300 Areamentioning

confidence: 99%

Section: The Hanford Site and The 300 Areamentioning

confidence: 99%

Section: The Hanford Site and The 300 Areamentioning

confidence: 99%

Section: Model Configuration Numerical Experiments and Analysesmentioning

confidence: 99%

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Coupling a three-dimensional subsurface flow and transport model with a land surface model to simulate stream–aquifer–land interactions (CP v1.0)

et al. 2017

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“…Examples of some uses of these types of data are provided by Oostrom et al (2006), and Williams et al (2008).…”

Section: Phasementioning

confidence: 99%

Status Report for Remediation Decision Support Project, Task 1, Activity 1.B ? Physical and Hydraulic Properties Database and Interpretation

Rockhold¹

2008

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Application of ensemble-based data assimilation techniques for aquifer characterization using tracer data at Hanford 300 area

et al. 2013

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[1] Subsurface aquifer characterization often involves high parameter dimensionality and requires tremendous computational resources if employing a full Bayesian approach. Ensemble-based data assimilation techniques, including filtering and smoothing, are computationally efficient alternatives. Despite the increasing use of ensemble-based methods in assimilating flow and transport related data for subsurface aquifer characterization, most applications have been limited to synthetic studies or twodimensional problems. In this study, we applied ensemble-based techniques adapted for parameter estimation, including the p-space ensemble Kalman filter and ensemble smoother, for assimilating field tracer experimental data obtained from the Integrated Field Research Challenge (IFRC) site at the Hanford 300 Area. The forward problem was simulated using the massively parallel three-dimensional flow and transport code PFLOTRAN to effectively deal with the highly transient flow boundary conditions at the site and to meet the computational demands of ensemble-based methods. This study demonstrates the effectiveness of ensemble-based methods for characterizing a heterogeneous aquifer by assimilating experimental tracer data, with refined prior information obtained from assimilating other types of data available at the site. It is demonstrated that high-performance computing enables the use of increasingly mechanistic nonlinear forward simulations for a complex system within the data assimilation framework with reasonable turnaround time.Citation: Chen, X., G. E. Hammond, C. J. Murray, M. L. Rockhold, V. R. Vermeul, and J. M. Zachara (2013), Application of ensemble-based data assimilation techniques for aquifer characterization using tracer data at Hanford 300 area, Water Resour. Res., 49,[7064][7065][7066][7067][7068][7069][7070][7071][7072][7073][7074][7075][7076]

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Three-Dimensional Groundwater Models of the 300 Area at the Hanford Site, Washington State

Cited by 43 publications

References 36 publications

Coupling a three-dimensional subsurface flow and transport model with a land surface model to simulate stream–aquifer–land interactions (CP v1.0)

Coupling a three-dimensional subsurface flow and transport model with a land surface model to simulate stream–aquifer–land interactions (CP v1.0)

Status Report for Remediation Decision Support Project, Task 1, Activity 1.B ? Physical and Hydraulic Properties Database and Interpretation

Application of ensemble-based data assimilation techniques for aquifer characterization using tracer data at Hanford 300 area

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