Groundwater flow to a pumping well in a sloping fault zone unconfined aquifer

Huang, Ching‐Sheng; Yang, Shaw Yang; Yeh, Hund‐Der

doi:10.1002/2013wr014212

Cited by 6 publications

(20 citation statements)

References 15 publications

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“…In fact, the topic of flow in a sloping aquifer has long been investigated [e.g., Henderson and Wooding, 1964;Huang et al, 2014]. Steady state solutions of the nonlinear Boussinesq equation for homogeneous unconfined flow in sloping aquifers with recharge have been derived analytically by McEnroe [1993], Verhoest and Troch [2000], Chapuis [2002], and Lo aiciga [2005].…”

Section: Introductionmentioning

confidence: 99%

Analytical solutions of seawater intrusion in sloping confined and unconfined coastal aquifers

Xin

Kong

et al. 2016

Water Resources Research

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Sloping coastal aquifers in reality are ubiquitous and well documented. Steady state sharp‐interface analytical solutions for describing seawater intrusion in sloping confined and unconfined coastal aquifers are developed based on the Dupuit‐Forchheimer approximation. Specifically, analytical solutions based on the constant‐flux inland boundary condition are derived by solving the discharge equation for the interface zone with the continuity conditions of the head and flux applied at the interface between the freshwater zone and the interface zone. Analytical solutions for the constant‐head inland boundary are then obtained by developing the relationship between the inland freshwater flux and hydraulic head and combining this relationship with the solutions of the constant‐flux inland boundary. It is found that for the constant‐flux inland boundary, the shape of the saltwater interface is independent of the geometry of the bottom confining layer for both aquifer types, despite that the geometry of the bottom confining layer determines the location of the interface tip. This is attributed to that the hydraulic head at the interface is identical to that of the coastal boundary, so the shape of the bed below the interface is irrelevant to the interface position. Moreover, developed analytical solutions with an empirical factor on the density factor are in good agreement with the results of variable‐density flow numerical modeling. Analytical solutions developed in this study provide a powerful tool for assessment of seawater intrusion in sloping coastal aquifers as well as in coastal aquifers with a known freshwater flux but an arbitrary geometry of the bottom confining layer.

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Section: Introductionmentioning

confidence: 99%

Analytical solutions of seawater intrusion in sloping confined and unconfined coastal aquifers

Xin

Kong

et al. 2016

Water Resources Research

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“…Comparison of the drawdown distribution versus time presented by our numerical solution and the solution of Huang et al (2014) with field data reported by Antonio and Pacheco (2002). …”

Section: Resultsmentioning

confidence: 69%

“…Generally, the upper boundary condition at the outcrop can be regarded as an infiltration curve which is treated as a boundary with recharge. Therefore, as shown in the study of Huang et al (2014), the outcrop boundary can be characterized by the free surface equation (similar to the water table), which can be expressed as:

K\frac{\partial s}{\partial z}=-{S}_y\frac{\partial s}{\partial t},z=W\sin \theta -s\ \mathrm{and}\ {x}_0\le x\le {x}_r,

where S y [−] represents the specific yield, W [L] represents the total length of the aquifer,

{x}_0=W\cos \theta -B/\left(\sin \theta \right)

, representing the location of the pumping well in the x ‐direction.

{x}_r=W\cos \theta

, representing the location of the outcrop in the x ‐direction.…”

Section: Conceptual Modelmentioning

confidence: 82%

“…Similarly, the values of K and S s at E5 were chosen as 0.009 m/d and 5.6 × 10 −7 1/m, respectively. Considering that the pumping test was conducted in a fracture zone aquifer, the actual value of the specific yield ( Sy ) was set to a small scale (i.e., Sy = 0.01), as Huang et al (2014) reported.…”

Section: Resultsmentioning

confidence: 99%

“…The numerical solution (finite difference code), on the other hand, was developed using MATLAB software considering the water table movement at the outcrop of the surface as well as wellbore storage. Both solutions were compared with the solution of Huang et al (2014). The behavior of the drawdown relative to pumping rate was elucidated.…”

Section: Discussionmentioning

confidence: 99%

See 2 more Smart Citations

Solutions for Groundwater Flow to a Pumping Well with an Exponentially Decreasing Variable‐Rate in a Sloping Aquifer

2022

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During aquifer pumping tests in the field, the attenuation process of the pumping rate is generally monitored, and the aquifer may be slanted, especially in riverbank terraces, piedmont plain and other similar terrains. The combination of these two factors (attenuation process and aquifer slope) has not received enough academic attention, therefore, a two‐dimensional groundwater flow model is developed for an exponentially decreasing variable rate pumping well in a sloping aquifer in this study. The new semi‐analytical solution (based on a linearized free‐surface boundary) is obtained using the Laplace transform and finite Fourier cosine transform. Meanwhile, to depict the linearized boundary precisely with the first‐order free surface equation, a numerical model that considers the decline of the water table is also developed. Results show that under the effect of the variable rate, the time‐drawdown curve presents a downward trend at intermediate times. Additionally, the error caused by the linearization of the free‐surface equation on the analytical model is found to be acceptable except when the sloping angle is larger than π/6. Furthermore, since this study extends the work of Huang et al. (2014), who considered a constant pumping rate, the new solution was found better to interpret real pumping test data reported by Antonio and Pacheco (2002), and the laboratory experiment results. Overall, the new solution proves to be useful for parameter inversion accurately as the average pumping rate tended to underestimate hydraulic parameters when fitting short‐term pumping data.

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New Analytical Solutions for Unsteady Flow in a Leaky Aquifer between Two Parallel Streams

Saeedpanah

Azar

2017

Water Resour Manage

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Groundwater flow to a pumping well in a sloping fault zone unconfined aquifer

Cited by 6 publications

References 15 publications

Analytical solutions of seawater intrusion in sloping confined and unconfined coastal aquifers

Analytical solutions of seawater intrusion in sloping confined and unconfined coastal aquifers

Solutions for Groundwater Flow to a Pumping Well with an Exponentially Decreasing Variable‐Rate in a Sloping Aquifer

New Analytical Solutions for Unsteady Flow in a Leaky Aquifer between Two Parallel Streams

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