Analytic Element Modeling of Steady Interface Flow in Multilayer Aquifers Using AnAqSim

This paper presents the analytic element modeling approach implemented in the software AnAqSim for simulating steady groundwater flow with a sharp fresh‐salt interface in multilayer (three‐dimensional) aquifer systems. Compared with numerical methods for variable‐density interface modeling, this app...

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Bibliographic Details
Published in:Ground water 2015-05, Vol.53 (3), p.432-439
Main Authors: Fitts, Charles R., Godwin, Joshua, Feiner, Kathleen, McLane, Charles, Mullendore, Seth
Format: Article
Language:English
Subjects:
Aquifers
Computer Simulation
Environmental Monitoring - methods
Fresh Water
Groundwater
Groundwater - chemistry
Saline water
Salinity
Seawater
Simulation
Software
Water flow
Water Movements
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Summary:This paper presents the analytic element modeling approach implemented in the software AnAqSim for simulating steady groundwater flow with a sharp fresh‐salt interface in multilayer (three‐dimensional) aquifer systems. Compared with numerical methods for variable‐density interface modeling, this approach allows quick model construction and can yield useful guidance about the three‐dimensional configuration of an interface even at a large scale. The approach employs subdomains and multiple layers as outlined by Fitts (2010) with the addition of discharge potentials for shallow interface flow (Strack 1989). The following simplifying assumptions are made: steady flow, a sharp interface between fresh‐ and salt water, static salt water, and no resistance to vertical flow and hydrostatic heads within each fresh water layer. A key component of this approach is a transition to a thin fixed minimum fresh water thickness mode when the fresh water thickness approaches zero. This allows the solution to converge and determine the steady interface position without a long transient simulation. The approach is checked against the widely used numerical codes SEAWAT and SWI/MODFLOW and a hypothetical application of the method to a coastal wellfield is presented.
ISSN:0017-467X
1745-6584
DOI:10.1111/gwat.12225