πŸ’§ IGW-NET Β· Quick Tutorial 4 of 31

Tutorial 4: Water Balance Analysis

Compute water budget terms (recharge, ET, well discharge, boundary fluxes) for the full model domain and custom sub-regions.

IGW-NET Tutorial 4 Prereq: MAGNET4WATER account 2 sections

This tutorial covers

  1. Fort Custer Aquifer Water Balance
  2. What's Next

1Fort Custer Aquifer Water Balance

Step 1 β€” Load Parent Model and Create Submodel

Click Save/Load Load to load the regional model from Tutorial 1. Click Simulate Run Submit to simulate, then add a submodel and apply 'Boundary Conditions from Parent Model' in the Default Model Input Parameters and Display Options Menu.

Step 2 β€” Add a River (Prescribed Head Boundary)

Click DrawLine button the 'DrawLine' and 'SaveShape' buttons to add a polyline feature along the Kalamazoo River. Assign this as a prescribed head boundary condition β€” the river stage is fixed, and the aquifer exchanges water with it depending on the head difference.

Step 3 β€” Add a Wetland Drain (One-Way Head-Dependent)

Click ZonePoly button the 'ZonePoly' and 'SaveShape' buttons to add a wetland zone near the Kalamazoo River. Assign this as a one-way head-dependent boundary condition (drain) β€” water can only leave the aquifer through the drain when the water table is above the drain elevation. Water cannot enter the aquifer from the drain.

Step 4 β€” Add a Lake (Two-Way Head-Dependent)

Click Zone tools ZonePoly the 'ZonePoly' button to add a lake zone on the east side of the Fort Custer area. Assign this as a two-way head-dependent boundary condition β€” the lake can both gain water from the aquifer (when water table is above lake level) and lose water to the aquifer (when lake level is above water table).

Step 5 β€” Add a Pumping Well

Click Well button showing well placement tool the 'Well' button to add a pumping well to the model domain. The well appears as a yellow dot on the map. Set the pumping rate in the well properties dialog.

Step 6 β€” Submit for Simulation

Click Submit button to submit the model for simulation. The solver computes the flow field with all boundary conditions active β€” river, drain, lake, recharge, and pumping well all interacting simultaneously.

Step 7 β€” View the Mass Balance Chart

Click Analysis button the 'Analysis' button, then select Display Charts option 'Display Charts' from the submenu. This launches analysis windows including the Mass Balance Bar Chart β€” showing every inflow and outflow component: recharge, river exchange, lake exchange, drain discharge, well pumping, and boundary fluxes. The chart quantifies exactly where water comes from and where it goes.

Step 8 β€” Save or Publish

Click Tools Save Save options to save or publish the model for future use.

Complete model showing Fort Custer area with all boundary conditions: Kalamazoo River as prescribed head polyline, wetland drain zone, lake zone, pumping well (yellow dot), and head contours showing flow towards discharge features
Figure 2: Complete conceptual model with all boundary conditions β€” Kalamazoo River (prescribed head), wetland drain (one-way head-dependent), lake (two-way head-dependent), and pumping well. Each feature contributes to the water balance.
Mass Balance Bar Chart showing inflows (recharge, river leakage in, lake leakage in, boundary flux in) and outflows (well pumping, drain discharge, river leakage out, lake leakage out, boundary flux out) as horizontal bars
Figure 3: Mass Balance Bar Chart β€” every source and sink quantified. Inflows on one side, outflows on the other. The budget must close: total in β‰ˆ total out. This is the health check of your model.

Key Concepts

Three types of head-dependent boundaries: Prescribed head (river β€” fixed stage, bidirectional flow), two-way head-dependent (lake β€” exchange depends on head difference, bidirectional), and one-way head-dependent (drain β€” water can only leave the aquifer, not enter). Each type has different physics and different impacts on the water balance.

The mass balance chart is automatic: Every boundary condition you add to the model is automatically reflected in the mass balance chart. No manual setup needed β€” the chart reads directly from the solver output. Add a feature β†’ simulate β†’ see its contribution to the budget immediately.

Mass balance as quality control: A large mass balance error (inflows β‰  outflows) indicates a numerical problem β€” the grid may be too coarse, the solver may not have converged, or a boundary condition may be poorly configured. Always check the mass balance before interpreting results.

2What's Next

With water balance analysis mastered, continue the learning path:

Tutorial 5: Contaminant Transport β€” add solute sources and simulate plume migration through the flow field you've built
Tutorial 6: Vertical Details β€” extend to 3D with multiple layers and confining units
Tutorial 7: Transient Modeling β€” add time-varying pumping, seasonal recharge, and dynamic water levels