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New taxonomy of clastic sedimentary structures and a procedure for its use in the simulation of groundwater flowMock, Peter Allen. January 1997 (has links)
This work describes a new taxonomy for elastic, sedimentary porous media. The taxonomy is synthesized for the investigation and characterization of ground-water flow from accumulating developments in the genetic analysis of elastic, sedimentary depositional structures. Genetic analysis recognizes spatial associations of elastic, sedimentary structures imposed during genesis. The taxonomy is a nested hierarchy of discrete elastic, sedimentary structures distinguished by the bounding surfaces created during their emplacement and rearrangement. The investigation and characterization of a specific ground-water flow system in elastic, sedimentary porous media can be improved by imposing a structural context on lithologie observations, geophysical measurements, head measurements, and hydraulic conductivity estimates. Globally-valid and transferable descriptions of structures in the taxonomy from modern exposures, outcrops, and densely sampled subsurface systems are modified to fit site-specific geologic observations and measurements. A specific procedure is developed for applying the taxonomy in the investigation and analysis of ground-water flow. The procedure quantitatively measures the hydraulic validity of alternative geologic interpretations of site-specific data under the taxonomy. The application of the taxonomy and procedure to a typical set of data types, densities, and quality is illustrated with data from a site of ground-water contamination investigation.
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Groundwater flow simulations and management under imprecise parametersShafike, Nabil Girgis. January 1994 (has links)
This dissertation considers modeling groundwater flow under imprecisely known parameters and managing a plume of contaminant. A new approach has been developed to study the effects of parameters uncertainty on the dependent variable, here the head. The proposed approach is developed based on fuzzy set theory combined with interval analysis. The kind of uncertainty modeled here is the imprecision associated with model parameters as a result of machine or human imprecision or lack of information. In this technique each parameter is described by a membership function. The fuzzy inputs into the model are in the form of intervals so are the outputs. The resulting head interval represents the change in the output due to interval inputs of model parameters. The proposed technique is illustrated using a two dimensional flow problem solved with a finite element technique. Three different cases are studied: homogeneous, mildly heterogeneous and highly heterogeneous transmissivity field. The groundwater flow problem analysis requires interval input values for the parameters, the output may be presented in terms of mean value, upper and lower bounds of the hydraulic head. The width of the resulting head interval can be used as a measure of uncertainty due to imprecise inputs. The degree of uncertainty associated with the predicted hydraulic head is found to increase as the width of the input parameters interval increases. Compared to Monte Carlo simulation approach, the proposed technique requires less computer storage and CPU time, however at this stage autocorrelation and crosscorolation are not configured in the presented formulation. In the plume containment problem two formulations are presented using the hydraulic gradient technique to control the movement of the contaminants. The first one is based on multiobjective analysis and the second, on fuzzy set theory. Multiobjective analysis yields a set of alternative strategies each of which satisfies the multiple objectives to a certain degree. Three different techniques have been used to choose a compromise strategy. Although they follow different principles, the same preferred strategies are selected. It is also noticed that rapid restoration results in a large pumping volumes and high costs. Using a fuzzy formulation for plume containment yields the optimum pumping rates and locations in addition to the membership function at each pumping location. The resulting membership functions at these pumping locations can be used to study the sensitivity of each location to a change in objective function and constraints bounds. Overall, both the fuzzy and multiobjective methodologies, presented in this dissertation, provide new and encouraging approaches to groundwater quality management.
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Laboratory evidence of the scale effect in solute transport through saturated porous mediaSilliman, Stephen Edward Joseph January 1981 (has links)
No description available.
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Recognizing groundwater as a site development limitation factorDavis, James Rodrick January 1984 (has links)
This study observes how the size and type of land development can often be limited by the supply of fresh groundwater sources. Multiple-use recharge basins were found to be effective in diverting pollutants around a potable source of groundwater, thus reducing the chances of that source becoming contaminated. A computer-aided numerical model was used to simulate groundwater flow and its responses to recharge basins in a hypothetical situation.Through a series of trials, artifical recharge was able to abate the problem of groundwater contamination in certain geohydrologic conditions. Optimum rates of recharge and discharge were determined to effectively divert contaminated groundwater around several types of developments. From these findings, land use options and development intensities can be safely recommended for areas which otherwise may have been nearly undevelopable. / Department of Landscape Architecture
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An effective medium approximation and Monte Carlo simulation in subsurface flow modelingShrestha, Surendra Prakash 19 June 2006 (has links)
An effective medium approximation and a refined Monte Carlo simulation procedure for solving the stochastic groundwater flow problem are presented. The effective medium approximation permits one to solve the stochastic groundwater flow problem in a single run to generate the expected pressure head field. The proposed effective hydraulic conductivity expression for the effective medium is of the same form as the local Gardner’s equation and is easy to use.
The refined Monte Carlo simulation procedure uses analytical means to estimate the sample size by controlling the error incurred in using the sample average in place of its population mean at a chosen confidence level. This estimator consistently performs well. Also, a variance reducing estimator which is different from the simple average for pressure head is developed. This estimator takes advantage of the correlation between the saturated conductivity and the pressure head distribution to reduce the output variance and is unbiased. This reduced variance results in a smaller width of uncertainty about the predicted pressure head. Both the effective medium approximation and the Monte Carlo approaches perform well when applied to several problems. / Ph. D.
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Simulation Of Groundwater Flow In The Rincon Valley Area And Mesilla Basin, New Mexico And TexasWeeden, A. Curtis,Jr., Maddock, Thomas, III 30 September 1999 (has links)
A groundwater flow model was constructed for the Rincon Valley area and Mesilla
Basin. The system is dominated by the complex interaction of the Rio Grande, canals, laterals,
and drains with groundwater pumping. The primary purpose of the model was to aid the New
Mexico -Texas Water Commission in assessing options for water resources development in the
Lower Rio Grand Basin from Caballo Reservoir in New Mexico to El Paso, Texas. One such
assessment was to evaluate the effect of secondary irrigation releases from Caballo Reservoir on
the water budget. In addition, the model will eventually be linked to a surface water model
(BESTSM) being utilized by the New Mexico -Texas Water Commission to evaluate water
supply alternatives for El Paso, Texas.
Stress periods were specified on a seasonal basis, a primary irrigation season from March
through October and a secondary irrigation season from November through February. Analysis
of model output indicates that groundwater pumping decreases Rio Grande flows, secondary
irrigation season releases do not alter the water budget significantly, and that recharge and
discharge from aquifer storage are strongly related to the season.
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Simulation of soil water movement model (SWaMM) using the Spider Distributed SystemWang, Li 01 January 2003 (has links)
This project implements a real application on the Spider II, which is a simulation of Soil Water Movement Model. The main objectives of this project were to develop a parallel and distributed algorithm for the Soil Water Model; implement the Soil Water Movement Simulation model on the Spider II distributed system and to evaluate the performance of simulating the Soil Water Movement Model on Spider II.
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Design of a field scale project for surfactant enhanced remediation of a DNAPL contaminated aquiferBrown, Chrissi Lynn 28 August 2008 (has links)
Not available / text
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