Abstract
This study examined two key aspects of reactive transport modeling for stream restoration purposes: the accuracy of the nutrient spiraling and transient storage models for quantifying reach-scale nutrient uptake, and the ability to quantify transport parameters using measurements and scaling techniques in order to improve upon traditional conservative tracer fitting methods. Nitrate (NO3-) uptake rates inferred using the nutrient spiraling model underestimated the total NO3- mass loss by 82%, which was attributed to the exclusion of dispersion and transient storage. The transient storage model was more accurate with respect to the NO3- mass loss (±20%) and also demonstrated that uptake in the main channel was more significant than in storage zones. Conservative tracer fitting was unable to produce transport parameter estimates for a riffle-pool transition of the study reach, while forward modeling of solute transport using measured/scaled transport parameters matched conservative tracer breakthrough curves for all reaches. Additionally, solute exchange between the main channel and embayment surface storage zones was quantified using first-order theory. These results demonstrate that it is vital to account for transient storage in quantifying nutrient uptake, and the continued development of measurement/scaling techniques is needed for reactive transport modeling of streams with complex hydraulic and geomorphic conditions.
Original language | English (US) |
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Pages (from-to) | 1018-1032 |
Number of pages | 15 |
Journal | Journal of Hydraulic Engineering |
Volume | 136 |
Issue number | 12 |
DOIs | |
State | Published - Apr 2010 |
Keywords
- Fluvial Hydraulics
- Nutrient loads
- Restoration
- Surface waters
- Transport phenomena