Leaky Aquifer Research Articles

Volumetric Approach to type Curves in leaky Aquifers

A nonequilibrium formula in terms of the depression cone volume is used to predict the drawdown variations in a fully penetrating large diameter well discharging from a leaky aquifer. The derivation of the formula is based on the continuity and Darcy laws. Sets of type curves are presented to find the aquifer and aquitard hydraulic properties. The asymptotic curves, as the leakage diminishes to zero, approximate the type curves for large diameter wells in confined aquifers. Leaky aquifer type curves for drawdowns in the producing well have three distinctive portions. The initial portion is a straightline and it reflects the effect of the well storage. It does not provide any relevant information about either the aquifer or the semipervious layer hydraulic properties. The second portion is a transition from the well storage effect to the complete leakage effect only. The last portion is a horizontal line corresponding to the steady state flow due to leakagev. In fact, the second portion is the most signifi...

A GENERAL PURPOSE MICROCOMPUTER AQUIFER TEST EVALUATION TECHNIQUE

Abstract. Although determination of aquifer characteristics from pumping test data is generally carried out using type curves or other graphical techniques, a number of computer methods have been developed recently for this purpose. Based on the principle of least squares, these methods of nonlinear regression analysis can be applied to any flow system for which analytical expressions of the drawdown distribution are known. In view of the growing general interest in the application of microcomputers in ground‐water hydrology, a BASIC routine has been developed for estimating any number of aquifer parameters. The least squares solution is calculated by Marquardt's algorithm, using the singular‐value decomposition of the Jacobian matrix. The robust computing method obtained can be applied to all kinds of pumping tests. Aquifer characteristics as well as their standard deviations are computed with optimal speed and accuracy. The technique is demonstrated by a simple application to steady flow in a leaky aquifer and an example is provided. Other applications are easily implemented and programs for unsteady‐state aquifer tests, recovery tests and multiple aquifer tests are available.

A Reinvestigation of the Analytical Solution for Drawdown Distributions in a Finite Confined Aquifer

A finite aquifer is an aquifer in which drawdown variations reflect the influence of the exterior boundary. By making use of Laplace transform the transient solution for drawdown distributions in a finite confined aquifer surrounded by constant‐head boundary is reinvestigated. The development of the solution was facilitated by using the available steady state solution for drawdown distributions in a leaky artisian aquifer with constant leakage. The solution obtained consists of the Theis solution and other functions which are responsible for the influence of the exterior boundary. Methods of evaluating the solution are given, and results are presented in type curves. A time criterion is determined approximating the duration during which an ideal aquifer (i.e., the aquifer is homogeneous, isotropic, and of uniform thickness) can property be analyzed as an infinite one. This relationship interrelates time with the given hydrogeological properties.

Unsteady flow to a ditch from a semi-confined and leaky aquifer

Flow situation into a ditch resulting from an aquifer that is semi-confined and leaky is investigated. Theoretical solution employing Fourier Series is given and then compared with that obtained by the Laplace Transformation.

Steady groundwater flow in leaky multiple-aquifer systems

The hydraulic properties of stratified formations usually vary from layer to layer. Within the area of influence of a pumped well, drain, or section of a river, the subsoil can often be schematized into a limited number of aquifers each separated by less pervious layers. A general method has been developed for the analytical solution of steady flow problems in leaky multiple-aquifer systems comprising any number of aquifers. This method has been used to investigate potential distributions in multilayered aquifers of infinite extent, being pumped or recharged at a constant rate using completely penetrating wells and drains in one or more of the aquifers. The same approach is applicable to groundwater flow problems with more complicated boundary conditions, such as the influence of a wide river partially penetrating the leaky top-layer. The well flow solution has been applied to evaluate hydraulic properties of several aquifers and aquitards from pumping-tests in a six-layer leaky aquifer system. In a general sense the method presented may be regarded as a combined analytical-numerical technique.

Mahdi S. Hantush 1921”1984

Mahdi Salih Hantush, Professor of Hydrology at the University of Kuwait, died on January 14, 1984 from complications following heart surgery.A hydrologist, scientist, and great teacher, Mantush specialized in the application of mathematics to the solution of transient groundwater flow problems. His particular expertise in the development of well‐flow equations led the late R.W. Stallman of the U.S. Geological Survey to refer to him as “The Master of Radial Flow.” Hantush's numerous scientific publications contributed greatly to the present theories of flow in leaky aquifers, unconfined aquifers, and anisotropic aquifers. He derived the mathematical equations of flow to fully and/or partially penetrating wells in such aquifer systems, and devised methods for the analysis of pumpingtest data to determine their hydraulic properties. He was not only a researcher, but also a practicing hydrologist, deriving the equations he needed to solve practical problems.

Perturbation Analysis of Nearly Horizontal Flows in Leaky Aquifers

A perturbation method is used to analyze the equations governing flows in two aquifers separated by a semipervious stratum. The upper aquifer is phreatic (unconfined), while the lower one is semiconfined. The nearly horizontal flow approximation produces a coupled system of equations for both aquifers which, in particular, is nonlinear for the phreatic region. A parameter perturbation technique is shown as a convenient way of linearizing and uncoupling the equations. Analytical solutions of the perturbed equations for two simple problems are presented.

Buildup Analysis for Interference Tests in Stratified Formations

Summary Interlayered crossflow modifies the responses of both the producing layer and the supporting less-permeable layer in such a manner that the conventional analysis based on the Ei type-curve graphical method becomes no longer valid. A forced match of pressure data from a stratified formation to the Ei type curve results in overestimation of both the formation storage and the permeability. Type curves that take into account the interlayered crossflow are developed and applied to analyze buildup data from interference tests at a water injectivity test site, Prudhoe Bay, AK. Introduction Vertical heterogeneity formed by a depositional sequence of interbedded, fine-grain sandstone and shale is a characteristic of the Prudhoe Bay reservoir. For example, Fig. 1 gives the shale correlation diagram developed from well logs for a Prudhoe Bay field water injectivity test site. 1 The cross sections show the presence of shaly sands of various thickness and continuity that overlie and underlie the field producing intervals. The extent and vertical permeability of these shaly sands will determine whether the reservoir permeable zones are in vertical hydraulic communication with the producing interval. If shales are continuous and have a negligible permeability, they form a barrier practically impermeable to flow. If, however, shaly sands that separate permeable reservoir layers have a measurable permeability or if they are discontinuous, then the production of an intermediate permeable zone will be enhanced by induced flow from the adjoining zones. The time-variant crossflow that augments the flow of a producing zone is dependent on the shaly sands' "leaking" properties-thickness, permeability, and the pressure difference across the sands-and on the amount of fluid that may be released from the reservoir volume extended by the contributing formations. Neither the producing zone with augmented flow nor the supporting zone with induced crossflow will, however, have the purely radial flow pattern implicit in any conventional analysis method. Customarily used buildup analyses-namely, those based on application of the Ei type curve for interference well testing and on the Homer analysis technique for single-well testing-are developed strictly for reservoirs with radial flow to a well. Therefore, if one applies the conventional analysis technique to pressure data measured in a producing zone "enlarged" by supporting flow formations, the formation permeability so determined will be overestimated by an amount proportional to the formation flow enhancement. Application of the Ei type-curve methods to a supporting zone with induced vertical flow impaired by low-permeability shaly sands is even less justified, since it is only radial flow that the exponential integral pressure curve describes. Recognition of alterations produced by crossflow is important for interpretation of pressure data, expecially if one analyzes the responses of a reservoir during a limited time of well testing. Here, a transient flow behavior is considered for both producing, and supporting layers when the interlayered crossflow is taken into account. The analysis of crossflow is made for two different assumptions: when it is assumed to be permeability controlled only and when it results front a diffusion mechanism of fluid transfer through the lowpermeability supporting zone. The first, the permeability-controlled or lumped-parameter crossflow assumption, implies that the entire storage of the supporting zone contributes to the crossflow equally at any time, without adding any time dependency to the flux resulting from vertical position of the point of observation. The second the diffusivity-controlled or distributed-parameter crossflow, implies that the amount of storage contributing to the crossflow increases with time starting with that adjacent to the layer interface and including finally the entire storage of the lowpermeability layer at pseudosteady state. The resulting pressure behavior, therefore, will be dependent on position as well as time, the time variation at any given position as well as time, the time variation at any given position being different from that predicted by the lumped-parameter approach. Both assumptions are used extensively in hydrogeology literature in developments of leaky aquifers, confined two-aquifer system, unconfined flows, and aquifer-aquitard systems. Both approaches are in use as well in the flow description of naturally fractured reservoirs. Quantitative aspects of transient flow behavior under the two different assumptions on crossflow are discussed in detail elsewhere. Here, an extension is made to a stratified reservoir, the responses of which are affected by crossflow. Pressure Behavior of a Producing Zone Augmented by Crossflow Suppose that the shaly sections overlying or underlying the producing reservoir layers do not form absolute flow barriers but have a certain permeability. Selective reservoir production will then cause a differential pressure depletion and a fluid flow from (or through) the adjoining low-permeability beds. JPT P. 301^

A mathematical model for regional land subsidence due to pumping: 3. Integrated equations for a phreatic aquifer

A mathematical model is developed for the areal distribution of drawdown, land subsidence, and horizontal displacements due to groundwater pumping from a deformable phreatic aquifer. This paper is a continuation of earlier works published by the authors (Bear and Corapcioglu, 1981a, b) on the subject of regional land subsidence due to pumping in confined and leaky aquifers. All the basic assumptions underlying these previous works are also valid here. However, in this case the same methodology is extended to the case of a phreatic aquifer. The main additional feature in the present paper is that due to the decline of the water table, the total stress at points within the flow domain changes continuously. Following the development of a three‐dimensional mathematical model consisting of a mass conservation equation, quasi‐static equilibrium equations, and stress‐strain relations for an assumed perfectly elastic solid matrix, a regional, horizontal two‐dimensional model is derived by averaging the three‐dimensional model over the vertical thickness of the aquifer, taking into account the continuous variation in total stress as a result of water table fluctuations. The separation of an initially coinciding phreatic surface, which serves as the Upper boundary of the aquifer, and a surface consisting of a set of solid particles during the lowering of the water table and the compaction of the aquifer has been incorporated into the averaging procedure. An analytical solution is given for the case of a single pumping well. The solution, which is expressed in terms of the classical well function for a confined aquifer but with a modified storativity, provides estimates of drawdown, vertical subsidence, and horizontal displacement. The displacements for a sample problem are compared with those of a confined aquifer under similar conditions. The results indicate that under the conditions of the studied case of radial flow, vertical and horizontal displacements due to pumping from a phreatic aquifer with the same discharge rate would be less than those of a confined one. Furthermore, the same averaging procedure is extended for a system of phreatic and leaky confined aquifers and for the unsaturated zone above the water table. An additional change in total stress is obtained in terms of moisture content of the zone above the phreatic surface.

GROUND‐WATER UNIT STEP AND RECTANGULAR PULSE RESPONSES WITH A PROGRAMMABLE CALCULATOR

AbstractA programmable calculator program is given along with examples for a general impulse response function for calculating step and rectangular pulse response for stream‐aquifer interaction, pumping in leaky and nonleaky artesian aquifers, and two‐dimensional dispersion.

The Noordbergum Effect and Characterization of Aquitards at the Rio Maior Mining Project

ABSTRACTThe planned exploitation of the Rio Maior lignite deposits will require a major dewatering program involving a thick leaky sand aquifer, and a heterogeneous and anisotropic aquitard complex. Diatomite, lignite, and clay are the main lithologies found in this aquitard complex. Characterization of the sand aquifer was accomplished by performing pumping tests with interpretations for steadystate and nonsteady‐state conditions. Aquitards were characterized by using both laboratory and field tests to determine hydraulic conductivity. Field methods were either those commonly adapted to leaky aquifers using water‐level data taken from observation wells tapping the underlying sand aquifer or those using water‐level data taken from piezometers located at the same distance from the pumping well and screened in the aquitard and in the aquifer. Field values of hydraulic conductivity are greater than laboratory values. In several piezometers the Noordbergum effect was observed during pumping tests. Redistribution of the loads originated by the pumping in the underlying sand aquifer is considered to be responsible for the reverse water‐level response in the overlying lignite‐diatomite complex. The Noordbergum effect has some influence in the application of the ratio method. On a practical basis, it seems reasonable to use the Noordbergum effect to compute drawdowns in the aquitards, and this leads to somewhat higher values for vertical hydraulic conductivities.

DISCUSSION OF “Analysis of Leaky Aquifer Pumping Test Data: An Automated Numerical Solution Using Sensitivity Analysis,” by P. M. Cobb, C. D. McElwee, and M. A. Butt, May‐June 1982 issue, v. 20, no. 3, pp. 325–333

DISCUSSION OF “Analysis of Leaky Aquifer Pumping Test Data: An Automated Numerical Solution Using Sensitivity Analysis,” by P. M. Cobb, C. D. McElwee, and M. A. Butt, May‐June 1982 issue, v. 20, no. 3, pp. 325–333

Delayed yield. An exact quasi-three dimensional model for free-aquifers

Quasi-three-dimensional models have been quite successful in the numerical treatment of leaky aquifers. Similar models are not available for free aquifers, except for Boulton's theory which can be properly interpreted as such. In the present paper a quasi-three-dimensional model of free surface flows is developed for free aquifers and waves. The zero-order approximation of this model yields Boulton's theory of delayed yield, elucidating in this manner the nature of the latter theory. The model presented here possesses numerical and theoretical possibilities which will be explored more thoroughly in further work.

An eigenvalue numerical technique for solving unsteady linear groundwater models continuously in time

A procedure for solving the differential groundwater flow equation is presented herein. Using a finite difference or finite element discretization scheme, a set of simultaneous linear equations is obtained. The eigenvalues and eigenvectors of a matrix, which is a function of the coefficients of the set, are the key to the solution. A vector L is obtained straightforwardly by combining the eigenvector matrix A, the eigenvalue vector α, the pumping vector P, and the initial head vector H. Vector L, which depends on time, can be expressed simply and explicitly as a function of the eigenvalues. Piezometric heads can be obtained by combining A and L. L is the only vector that needs to be computed as P changes with time. In this way, influence functions of a piezometric head, flow velocity and flow depletion of a stream connected with the aquifer under a unit stress, can be obtained explicitly and continuously in time. The method can be applied to confined as well as to leaky aquifers and to one‐, two‐, or three‐ dimensional linear models. Its main advantage lies in the fact that it is unnecessary to repeatedly solve a matrix for every time increment. The method is particularly useful for groundwater management problems in which a large number of alternatives have to be evaluated.

A Quantitative Model to Predict a Safe Yield for Well Fields in Kufra and Sarir Basins, Libya.

The Kufra and Sarir basins of Libya have huge ground-water resources. Three well fields-Sarir, Kufra, and Jalo-have been constructed for irrigation purposes. The Tazerbo and West Sarir well fields are under construction. Wells in these well fields have tapped only a small portion of the total ground water available. The hydrological behavior of the Sarir well field (determined by using analytical and numerical models) indicated a leaky artesian aquifer and a significant partial penetration effect. Long and short-term pump tests did not provide true estimates of the values of transmissivity and the coefficient of storage. A steady-state model of the Kufra and Sarir basins indicated a minimum of 80 m3 /s of underflow entering from Tibesti, Chad and Sudan. A transient model was constructed to pump a total of 120 m3 /s from 14 well fields. The simulation indicated that sufficient drawdown was available to last at least 50 years.

Transient two-dimensional groundwater flow

ABSTRACT A set of simple analytical solutions are presented for estimation of drawdowns and groundwater flow rates into two-dimensional excavation, such as those in open-cut strip mines, for confined, leaky and unconfined aquifers.

Well Hydraulics in Vertically Heterogeneous Formations

Comparative analysis of time-dependent drawdown alterations caused by the heterogeneous properties of stratified formations is given based on solutions developed under different assumptions on interlayered crossflow. The assumption of proportionality of leakage to the differential flow depletion, which is widely used in leaky aquifers developments, severely modifies the calculated drawdown values for both the aquifer and the aquitard as compared to those values obtained by assuming the diffusivity distribution process for the flow within each layer. The drawdown pattern is particularly affected at the early times. It is shown that if the compressibility of the low-permeability layer is taken into account, the shape of transient drawdown curves is a function not only of the ratio of permeabilities of the permeable and the semi-permeable layers but of the ratio of their storages as well.

In‐Situ Determination of Three‐Dimensional Aquifer Permeabilities

ABSTRACTIn conventional methods of aquifer tests, homogeneous and isotropic formations are assumed. In many instances, however, aquifers are anisotropic. To resolve this problem, three‐dimensional flow equations in homogeneous, anisotropic and leaky aquifers are derived. With the equation and method outlined in the report, we can determine the three components of directional permeability (x, y, and z) in the presence of leakage, and determine the statistical distribution of fractures and stream channels. Field tests that verify our theory are presented.

Numerical treatment of leaky aquifers in the short time range

The numerical treatment of leaky aquifers in the short time range is complicated because it requires the use of very refined meshes. This range of time includes not only pumping tests but also many regional studies because the definition of short time range depends on the thickness and diffusivity of the aquitard. The groundwater system of Mexico City is an example in which the short time range extends well beyond the whole life span of the pumping wells. In this paper a procedure which permits the avoidance, to a large extent, of these difficulties is explained; it is based on the integrodifferential equations approach. In addition a method that can be applied to control the error is presented.

Analysis of Leaky Aquifer Pumping Test Data: An Automated Numerical Solution Using Sensitivity Analysis

ABSTRACTThe Kansas Geological Survey is pursuing an effort to automate some of the more common methods of aquifer pumping‐test analysis. This paper discusses the results of work done on the leaky artesian aquifer as defined by Hantush and Jacob (1955). The paper covers the basic theory of the aquifer type, the numerical solution of the leaky artesian‐well function, and the methodology of achieving the “best fit” parameters in the least squares' sense. Several data sets are used to demonstrate the applicability of the proposed technique. These examples indicate the generally satisfactory results produced by the automated analysis documented here.The algorithm has good convergence properties. Initial estimates for the aquifer parameters may vary by about three orders of magnitude above or below the correct values. For typical data sets the rms fitting error should be less than a few tenths of a foot. If this is not the case, one is probably not dealing with a simple leaky aquifer. This method of pumping‐test analysis does not eliminate the role of an experienced hydrologist to define the local hydrogeology and aquifer type. However, once the decision is made as to which aquifer configuration is being observed, this program will, in a quick and unbiased fashion, give an accurate assessment of the leaky‐aquifer parameters within the limits of the theoretical approximations and the data quality.