Effective conductivity of heterogeneous aquifers in unsteady periodic flow

• Published in: Advances in water resources Vol. 62; pp. 317 - 326
• Main Authors: Rabinovich, A., Dagan, G., Miloh, T.
• Format: Journal Article
• Language: English
• Published: Kidlington Elsevier Ltd 01.12.2013; Elsevier
• Subjects: Aquifer flow; Earth sciences; Earth, ocean, space; Effective conductivity; Effective transmissivity; Exact sciences and technology; Heterogeneity; Hydrogeology; Hydrology. Hydrogeology; Time periodic; Effective conductivity; Effective transmissivity; Heterogeneity; Time periodic; Aquifer flow; transient flow; models; ground water; heterogeneity; confined aquifers; frequency; transmissivity; hydraulic conductivity; heterogeneous media; water resources; aquifers; three-dimensional models; two-dimensional models
• ISSN: 0309-1708; 1872-9657
• DOI: 10.1016/j.advwatres.2013.09.002

•Time periodic flow in heterogeneous aquifers of lognormal conductivity is considered.•We derive a complex dynamic effective conductivity Kef.•We illustrate the parameter dependence of Kef and the average head and flux.•We delineate the parameter ranges for which there is a significant dynamic effect.•We analyze the dynamic effective conductivity in specific applications. We consider transient flow in 3D and 2D (regional) confined aquifers with spatially variable random hydraulic conductivity K(x) (replaced by the transmissivity T(x) for regional flow). The latter is considered a function of lognormal univariate distribution, characterized by KG (the geometric mean) and σY2, the variance of Y=lnK. The aquifer is modeled as a layer/plane composed of densely distributed spherical/circular inclusions of different K, with time periodic head of frequency ω at the inlet and constant head at the outlet. The self consistent approximation is used to derive the effective conductivity Kef and the average head 〈H〉 and flux 〈q〉 fields are subsequently arrived at. In the common quasi-steady approximation, Kef is equal to the steady state effective property Kefst. We derive an expression for the frequency dependent Kef, which is generally complex, i.e., dynamic. The main result is the delineation of the ranges of the parameters ω,σY2 for which Kef,〈H〉 and 〈q〉 show a significant dynamic effect. We examine specific applications to show that generally the quasi-steady approximation is sufficiently accurate while delimiting the cases in which the dynamic effective conductivity is significant. It is also shown that the derived Kef applies to 2D phreatic flow with time periodic recharge.