Friday, 24 April, 2026
Interpreting Results
A simulation produces multiple 3D maps simultaneously: concentrations, metabolites, isotopic signatures, and residence times. Without a systematic reading method, this abundance of data can quickly become overwhelming. This page provides a structured approach to interpreting outputs, recognizing inconsistencies, and identifying zones or questions where the model provides decisive information.
Reading a Plume by Order of Questions
Rather than examining all outputs at once, it is more efficient to proceed through a sequence of questions. Each question points toward a specific visualization mode and prevents data fragmentation.
| Question | Target Visualization Mode | What to Observe |
|---|---|---|
| Where is the plume located? | Concentration isosurface (at regulatory threshold) | Footprint, dominant direction, leading edge |
| Has the plume reached deep levels? | Vertical cross-section along flow axis | Stratification, aquifer/aquitard interfaces |
| Are there multiple sources? | Horizontal slice at fixed depth | Multiple lobes, discontinuities |
| Is degradation active? | Parent/metabolite ratio map | Zones with low ratios (high degradation) |
| Which zones are isotopically active? | Residual δ - Initial δ map | Enriched zones (fractionation via degradation) |
| How does the plume evolve over time? | Temporal animation | Front progression, stabilization, or recession |
| What is the mass flux leaving the site? | Surface integration at downgradient boundary | Cumulative mass flux, instantaneous flow rate |
Comparison with Measurements
A simulation that fails to reproduce field measurements requires recalibration. Conversely, a simulation that matches them all perfectly is often over-fitted, which can mask weaknesses in predictions outside of sampling points. The recommended approach distinguishes between three comparison zones.
| Zone | Validation Criteria | Warning Signal |
|---|---|---|
| Calibration Points | Deviation smaller than measurement uncertainty | Higher deviation: inconsistent model |
| Validation Points (not used for calibration) | Correct order of magnitude | Deviation > factor of 10: model failure |
| Unsampled Zones | Consistency with known context | Prediction incompatible with geology |
The distinction between calibration points and validation points is essential. If all available data points are used to adjust the model, none remain to test its robustness elsewhere. Reserving one or two outlying boreholes as an independent test is a robust practice that requires discipline.
For a well-instrumented site, a pragmatic rule is to use approximately 75% of points for calibration and keep the remainder for validation. The deviation between prediction and measurement at validation points is a much better indicator of model quality than the deviation at calibration points, which can be artificially optimized.
Recognizing Internal Inconsistencies
Some inconsistencies appear directly in the results without requiring external comparison. Detecting them early prevents the publication of an invalid model.
- Concentration exceeding the source. If a downgradient point shows a concentration higher than the source, there is a configuration error (underestimated source, undeclared inflow, unstable time step).
- Leading edge moving faster than effective velocity. A plume cannot advance faster than v/R. If it does, either velocity is overestimated or the retardation factor R was not applied.
- Dominant metabolite without a parent in any zone. A metabolite can only exist where its parent has been present. Complete isolation suggests an initialization error or a kinetic coupling failure.
- Isotopic signature inconsistent with concentration. In a high-degradation zone, one expects both a drop in concentration and an enrichment in isotopic signature. If both move in the same direction (dropping concentration without enrichment), it suggests dilution rather than degradation.
- Mass balance non-conservation. The engine displays the total mass balance. A significant drift is often the sign of a time step that is too large.
Sensitivity and Uncertainty
A result without an indication of uncertainty is potentially misleading. While the engine does not explicitly calculate global uncertainty, several qualitative indicators help frame its reliability.
| Indicator | Interpretation |
|---|---|
| Variability of known input parameters | Wider literature ranges imply higher uncertainty |
| Sampling point density | Well-instrumented zones yield more reliable predictions |
| Measurement reproduction deviation | Poor reproduction = high uncertainty everywhere |
| Temporal projection horizon | Uncertainty grows the further out we project |
| Multi-hypothesis comparison | Variation amplitude between plausible scenarios |
It is tempting to associate a single simulation with a precise figure and include it in a report as a reference value. This is almost always misleading. A range with low and high bounds, paired with the scenarios that produced them, provides a more honest communication of what the model can actually say.
Distinguishing What the Model Says vs. Does Not Say
A simulation model answers certain questions with reasonable reliability while remaining silent or hazardous on others. Categorizing questions correctly is one of the most valuable skills for a user of this tool.
| Type of Question | Typical Reliability |
|---|---|
| Order of magnitude of plume footprint | High (if hydrogeological conditions are well-defined) |
| Dominant flow direction | High (if piezometry is available) |
| Identification of active vs. passive zones | Moderate (requires local geochemical data) |
| Projected concentrations at a specific point | Moderate to Low (depending on time horizon) |
| Precise date of threshold exceedance | Low (high sensitivity to parameters) |
| Point-source origin of existing contamination | Low (if multiple plausible sources exist) |
Producing a Synthetic Interpretation
Moving from a raw model to a distributable interpretation requires summarizing what was observed, what was learned, and what remains uncertain. A three-paragraph framework helps structure this synthesis.
- What the model shows. Plume shape, active zones, concentration projections. Factual description without interpretation.
- What it means. Reading results in operational terms (resource is threatened, natural attenuation is sufficient, remediation is necessary).
- What remains open. Poorly constrained parameters, zones without data, hazardous projections beyond a certain horizon.
This three-step structure aligns perfectly with the **FAIH** philosophy (Factual, Analytical, Interpreted, Honest) used in the IsoFind Reports module. Drafting your interpretation in this framework during the simulation phase greatly simplifies the final report writing.
Learn More
- Multi-Hypothesis: Framing uncertainty through multiple scenarios.
- Export and Sharing: Extracting visualizations for reports.
- FAIH Philosophy: A writing framework consistent with this approach.