Your search keyword '"L. Van Dam"' showing total 6 results

1. Predicting flow and transport in highly heterogeneous alluvial aquifers

Author

James J. Butler, M. Dogan, David A. Benson, David W. Hyndman, Mark M. Meerschaert, Gaisheng Liu, Remke L. Van Dam, and Geoffrey C. Bohling

Subjects

geography, geography.geographical_feature_category, Groundwater flow, Environmental remediation, Flow (psychology), Aquifer, Soil science, Physics::Geophysics, Plume, Geophysics, Fractal, Hydraulic conductivity, General Earth and Planetary Sciences, Environmental science, Alluvial aquifer, Geotechnical engineering

Abstract

Successful prediction of groundwater flow and solute transport through highly heterogeneous aquifers has remained elusive due to the limitations of methods to characterize hydraulic conductivity (K) and generate realistic stochastic fields from such data. As a result, many studies have suggested that the classical advective-dispersive equation (ADE) cannot reproduce such transport behavior. Here we demonstrate that when high-resolution K data are used with a fractal stochastic method that produces K fields with adequate connectivity, the classical ADE can accurately predict solute transport at the macrodispersion experiment site in Mississippi. This development provides great promise to accurately predict contaminant plume migration, design more effective remediation schemes, and reduce environmental risks.

Published

2014

2. Electrical imaging and fluid modeling of convective fingering in a shallow water-table aquifer

Author

Brian P. Eustice, David W. Hyndman, Remke L. Van Dam, Warren W. Wood, and Craig T. Simmons

Subjects

Convection, geography, geography.geographical_feature_category, Natural convection, Aquifer, Geophysics, engineering.material, Physics::Geophysics, Physics::Fluid Dynamics, Waves and shallow water, Electrical resistivity and conductivity, engineering, Halite, Groundwater, Geology, Water Science and Technology, Fluid modeling

Abstract

Free to read Unstable density-driven flow can lead to enhanced solute transport in groundwater. Only recently has the complex fingering pattern associated with free convection been documented in field settings. Electrical resistivity (ER) tomography has been used to capture a snapshot of convective instabilities at a single point in time, but a thorough transient analysis is still lacking in the literature. We present the results of a 2 year experimental study at a shallow aquifer in the United Arab Emirates that was designed to specifically explore the transient nature of free convection. ER tomography data documented the presence of convective fingers following a significant rainfall event. We demonstrate that the complex fingering pattern had completely disappeared a year after the rainfall event. The observation is supported by an analysis of the aquifer halite budget and hydrodynamic modeling of the transient character of the fingering instabilities. Modeling results show that the transient dynamics of the gravitational instabilities (their initial development, infiltration into the underlying lower-density groundwater, and subsequent decay) are in agreement with the timing observed in the time-lapse ER measurements. All experimental observations and modeling results are consistent with the hypothesis that a dense brine that infiltrated into the aquifer from a surficial source was the cause of free convection at this site, and that the finite nature of the dense brine source and dispersive mixing led to the decay of instabilities with time. This study highlights the importance of the transience of free convection phenomena and suggests that these processes are more rapid than was previously understood.

Published

2014

3. Hydraulic conductivity fields: Gaussian or not?

Author

Remke L. Van Dam, David A. Benson, Mark M. Meerschaert, M. Dogan, and David W. Hyndman

Subjects

Hydrogeology, Groundwater flow, Gaussian, Statistical model, law.invention, symbols.namesake, Hydraulic conductivity, law, Histogram, Statistics, Ground-penetrating radar, symbols, Environmental science, Statistical physics, Radar, Water Science and Technology

Abstract

[1] Hydraulic conductivity (K) fields are used to parameterize groundwater flow and transport models. Numerical simulations require a detailed representation of the K field, synthesized to interpolate between available data. Several recent studies introduced high-resolution K data (HRK) at the Macro Dispersion Experiment (MADE) site, and used ground-penetrating radar (GPR) to delineate the main structural features of the aquifer. This paper describes a statistical analysis of these data, and the implications for K field modeling in alluvial aquifers. Two striking observations have emerged from this analysis. The first is that a simple fractional difference filter can have a profound effect on data histograms, organizing non-Gaussian ln K data into a coherent distribution. The second is that using GPR facies allows us to reproduce the significantly non-Gaussian shape seen in real HRK data profiles, using a simulated Gaussian ln K field in each facies. This illuminates a current controversy in the literature, between those who favor Gaussian ln K models, and those who observe non-Gaussian ln K fields. Both camps are correct, but at different scales.

Published

2013

4. Hydrostratigraphic analysis of the MADE site with full-resolution GPR and direct-push hydraulic profiling

Author

James J. Butler, Remke L. Van Dam, Geoffrey C. Bohling, M. Dogan, and David W. Hyndman

Subjects

geography, geography.geographical_feature_category, Aquifer, Soil science, law.invention, Geophysics, Hydraulic conductivity, law, Facies, Ground-penetrating radar, General Earth and Planetary Sciences, Geotechnical engineering, 3d geometry, Radar, Geology

Abstract

[1 ]F ull ‐resolution 3D Ground‐Penetrating Radar (GPR) data were combined with high‐resolution hydraulic conductivity (K) data from vertical Direct‐Push (DP) profiles to characterize a portion of the highly heterogeneous MAcro Dispersion Experiment (MADE) site. This is an important first step to better understand the influence of aquifer heterogeneities on observed anomalous transport. Statistical evaluation of DP data indicates non‐ normal distributions that have much higher similarity within each GPR facies than between facies. The analysis of GPR and DP data provides high‐resolution estimates of the 3D geometry of hydrostratigraphic zones, which can then be populated with stochastic K fields. The lack of such estimates has been a significant limitation for testing and parameterizing a range of novel transport theories at sites where the traditional advection‐dispersion model has proven inadequate. Citation: Dogan, M., R. L. Van Dam, G. C. Bohling, J. J. Butler Jr., and D. W. Hyndman (2011), Hydrostratigraphic analysis of the MADE site with full‐resolution GPR and direct‐push hydraulic profiling, Geophys. Res. Lett., 38, L06405, doi:10.1029/2010GL046439.

Published

2011

5. Natural free convection in porous media: First field documentation in groundwater

Author

Warren W. Wood, David W. Hyndman, Remke L. Van Dam, and Craig T. Simmons

Subjects

geography, geography.geographical_feature_category, Natural convection, Hydrogeophysics, Aquifer, Geophysics, Natural (archaeology), Planetary science, General Earth and Planetary Sciences, Electrical resistivity tomography, Geology, Groundwater, Waste disposal

Abstract

[1] Natural free convection is a process of great importance in disciplines from hydrology to meteorology, oceanography, planetary sciences, and economic geology, and for applications in carbon sequestration and nuclear waste disposal. It has been studied for over a century – but almost exclusively in theoretical and laboratory settings. Despite its importance, conclusive primary evidence of free convection in porous media does not currently exist in a natural field setting. Here, we present recent electrical resistivity measurements from a sabkha aquifer near Abu Dhabi, United Arab Emirates, where large density inversions exist. The geophysical images from this site provide, for the first time, compelling field evidence of fingering associated with natural free convection in groundwater.

Published

2009

6. Subsurface imaging of vegetation, climate, and root-zone moisture interactions

Author

David W. Hyndman, Dushmantha H. Jayawickreme, and Remke L. Van Dam

Subjects

Hydrology, Geophysics, Moisture, Evapotranspiration, Streamflow, General Earth and Planetary Sciences, Environmental science, Global change, Ecotone, Land cover, Groundwater recharge, Water content

Abstract

[1] Changes in global climate and land use affect important processes from evapotranspiration and groundwater recharge to carbon storage and biochemical cycling. Near surface soil moisture is pivotal to understand the consequences of these changes. However, the dynamic interactions between vegetation and soil moisture remain largely unresolved because it is difficult to monitor and quantify subsurface hydrologic fluxes at relevant scales. Here we use electrical resistivity to monitor the influence of climate and vegetation on root-zone moisture, bridging the gap between remotely-sensed and in-situ point measurements. Our research quantifies large seasonal differences in root-zone moisture dynamics for a forest–grassland ecotone. We found large differences in effective rooting depth and moisture distributions for the two vegetation types. Our results highlight the likely impacts of land transformations on groundwater recharge, streamflow, and land-atmosphere exchanges.

Published

2008