Robust Representation of Dry Cells in Single‐Layer MODFLOW Models

Painter, S. L.; Başağaoğlu, Hakan; Liu, Angang

doi:10.1111/j.1745-6584.2008.00483.x

Cited by 22 publications

(52 citation statements)

References 17 publications

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“…This numerical artifact of MODFLOW could have been avoided by applying an upstream weighting of transmissivities (e.g., Painter et al 2008) at the cell faces representing dewatered shaft, that is, T M 1/2 = T 1 = K z. MODFLOW interface transmissivity, T M 1/2 , is usually calculated as a harmonic or arithmetic mean of the transmissivities in the adjacent cells, that is, T 0 and T 1 .…”

Section: Seepage Into Dewatered Shaftmentioning

confidence: 99%

Simulating Seepage into Mine Shafts and Tunnels with MODFLOW

Zaidel¹,

Markham

Bleiker

2010

Groundwater

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In cases when an equivalent porous medium assumption is suitable for simulating groundwater flow in bedrock aquifers, estimation of seepage into underground mine workings (UMWs) can be achieved by specifying MODFLOW drain nodes at the contact between water bearing rock and dewatered mine openings. However, this approach results in significant numerical problems when applied to simulate seepage into an extensive network of UMWs, which often exist at the mine sites. Numerical simulations conducted for individual UMWs, such as a vertical shaft or a horizontal drift, showed that accurate prediction of seepage rates can be achieved by either applying grid spacing that is much finer than the diameter/width of the simulated openings (explicit modeling) or using coarser grid with cell sizes exceeding the characteristic width of shafts or drifts by a factor of 3. Theoretical insight into this phenomenon is presented, based on the so-called well-index theory. It is demonstrated that applying this theory allows to minimize numerical errors associated with MODFLOW simulation of seepage into UMWs on a relatively coarse Cartesian grid. Presented examples include simulated steady-state groundwater flow from homogeneous, heterogeneous, and/or anisotropic rock into a vertical shaft, a horizontal drift/cross-cut, a ramp, two parallel drifts, and a combined system of a vertical shaft connected to a horizontal drift.

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Section: Seepage Into Dewatered Shaftmentioning

confidence: 99%

Simulating Seepage into Mine Shafts and Tunnels with MODFLOW

Zaidel¹,

Markham

Bleiker

2010

Groundwater

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“…This may be achieved via 'engineering out' the problems of drying by modifying the model (e.g. thickening of layers), altering the source code to remove the potential for drying (Hydrogeologic 1996;Doherty 2001;Painter et al 2008;Keating & Zyvoloski 2009) and/or by reducing the frequency or effect of rewetting by alteration of resaturation or solver-based parameters (McDonald et al 1991). A composite of these methods was useful in the development of the joined NEAC groundwater model.…”

Section: Overcoming Difficulties Of Large Joined Modelsmentioning

confidence: 99%

Crossing boundaries, the influence of groundwater model boundaries and a method to join and split MODFLOW models

Black¹,

Lewis²,

Grout

et al. 2012

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Neighbouring groundwater models often have large areas of overlap to avoid boundary issues in hydrogeological assessments and such overlap or artificial boundaries can lead to inconsistent representations of aquifers and processes. This paper presents the aggregation of six adjacent models spanning East Anglia, England, into one model without internal boundaries. This study principally discusses the effect of, and difficulties arising from model edge boundaries. In addition, a review of conceptual and numerical discontinuities at model boundaries is included and a more consistent and robust modelling approach over the whole area is demonstrated. The large, joined model is used to delineate groundwater divides, assess their transient migration, review edge boundary implications for water balances and investigate abstraction impacts without the influence of internal static boundaries. Computer codes developed in conjunction with this study facilitate joining adjacent models and, conversely, splitting of the joined model back into models at the scale of the original component models using simulated groundwater divides, or to smaller submodels incorporating edge boundary conditions calculated from the parent model.

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“…The first versions of the widely used groundwater flow model MODFLOW (McDonald and Harbaugh 1988) had a sure but inflexible way of handling unconfined finite‐difference aquifer cells where the water table dropped below the bottom of the cell—these “dry cells” were turned inactive for the remainder of the simulation. Problems with this formulation were easily seen, including the potential for inadvertent loss of simulated recharge in the model (Doherty 2001; Painter et al 2008), and rippling of dry cells through the solution that unacceptably changed the groundwater flow system (Juckem et al 2006). Moreover, solving problems of the natural world often required the ability to reactivate dry cells when the water table rose above the cell bottom.…”

Section: Introductionmentioning

confidence: 99%

“…Early attempts at “re‐wetting” dry cells in MODFLOW, such as BCF2 (McDonald et al 1992) were found to work for some, but not all, MODFLOW models. Re‐wetting of dry cells was often numerically unstable and prevented model convergence (Doherty 2001; Painter et al 2008). When BCF2 did have a stable solution, the resulting runtimes were appreciably longer, the effort to select suitable BCF2 settings was often large, and the solution did not robustly handle input perturbations of parameter estimation (Doherty 2001).…”

Section: Introductionmentioning

confidence: 99%

“…Moreover, there were still large numbers of groundwater flow problems that remained unstable even with this modification (Doherty, written communication, 2012). Thus, even though some proprietary versions of MODFLOW had better handling of dry cells, many modelers substituted shortcuts within MODFLOW; shortcuts such as assuming all layers were confined, artificially lowering cell bottoms, and large convergence criteria—non‐physical adjustments that “could raise questions about the accuracy and reliability of the model results” (Painter et al 2008).…”

Section: Introductionmentioning

confidence: 99%

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