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- Title
Core-scale solute transport model selection using Monte Carlo analysis.
- Authors
Malama, Bwalya; Kuhlman, Kristopher L.; James, Scott C.
- Abstract
[1] Model applicability to core-scale solute transport is evaluated using breakthrough data from column experiments conducted with conservative tracers tritium (³H) and sodium-22 (22Na), and the retarding solute uranium-232 (232U). The three models considered are single-porosity, double-porosity with single-rate mobile-immobile mass-exchange, and the multirate model, which is a deterministic model that admits the statistics of a random mobile-immobile mass-exchange rate coefficient. The experiments were conducted on intact Culebra Dolomite core samples. Previously, data were analyzed using single-porosity and double-porosity models although the Culebra Dolomite is known to possess multiple types and scales of porosity, and to exhibit multirate mobile-immobile-domain mass transfer characteristics at field scale. The data are reanalyzed here and null-space Monte Carlo analysis is used to facilitate objective model selection. Prediction (or residual) bias is adopted as a measure of the model structural error. The analysis clearly shows single-porosity and double-porosity models are structurally deficient, yielding late-time residual bias that grows with time. On the other hand, the multirate model yields unbiased predictions consistent with the late-time -5/2 slope diagnostic of multirate mass transfer. The analysis indicates the multirate model is better suited to describing core-scale solute breakthrough in the Culebra Dolomite than the other two models.
- Subjects
TRACERS (Chemistry); TRITIUM; SODIUM; URANIUM isotopes; POROSITY; DOLOMITE; MASS transfer; MONTE Carlo method
- Publication
Water Resources Research, 2013, Vol 49, Issue 6, p3133
- ISSN
0043-1397
- Publication type
Article
- DOI
10.1002/wrcr.20273