Assessing controls on selenium fate and transport in watersheds using the SWAT model

• Published in: The Science of the total environment Vol. 738; p. 140318
• Main Authors: Neupane, Pratikshya, Bailey, Ryan T., Tavakoli-Kivi, Saman
• Format: Journal Article
• Language: English
• Published: Elsevier B.V 10.10.2020
• Subjects: aquifers; Arkansas River; Colorado; environment; food chain; Groundwater; groundwater flow; hydraulic conductivity; irrigation; irrigation water; nitrates; oxygen; river valleys; runoff; selenates; selenites; Selenium; Sensitivity analysis; shale; simulation models; Soil and Water Assessment Tool model; soil water; stream flow; streams; sulfur; surface water; SWAT; toxicity; water management; Watershed modeling; watersheds; Arkansas River; Colorado; SWAT; Sensitivity analysis; Selenium; Groundwater; Watershed modeling
• ISSN: 0048-9697; 1879-1026; 1879-1026
• DOI: 10.1016/j.scitotenv.2020.140318

Selenium toxicity in groundwater and surface water in many regions globally has resulted in toxicity in the food chain thus harming terrestrial and aquatic animals. Here we assess the environmental controls on selenium fate and transport in soils, groundwater, and rivers at the watershed scale using the SWAT watershed simulation model. We modify the SWAT modeling code to simulate selenium fate and transport in surface runoff, lateral flow, soil percolation, groundwater flow, streamflow, and irrigation water within a watershed subject to oxidation-reduction reactions. This modified SWAT model is applied to an irrigated watershed with selenium problems in the Arkansas River Valley, Colorado. The model is calibrated and tested using observed groundwater and surface water selenium data in different locations of the study area, whereupon global sensitivity analysis is performed to assess controls on selenium fate and transport in soil water, groundwater and streams. The impacts of reaction rates of selenate, selenite, oxygen and nitrate along with 14 hydrologic parameters are assessed. For the baseline model, selenium loading to streams during growing season is mostly via groundwater discharge (365 kg/ha; 85% of total), followed by surface runoff (14%), and soil lateral flow (1%), which are about 4-fold the loading that occurs during non-growing season. Results from the sensitivity analysis indicate that hydrologic factors (timing of recharge, soil hydraulic conductivity, and groundwater storage thresholds) are the principal controls on selenium content in soils, groundwater, and stream water, followed by the first-order reaction rates of selenate and selenite, amount of selenium-bearing shale in the aquifer, and sulfur to selenium ratio in the shale material. These results suggest that selenium mitigation procedures should focus on water management practices rather than influencing microbial redox reactions. Overall, the SWAT-Se model introduced here can be used to assess Se contamination and mitigation practices in watersheds worldwide. [Display omitted] •Transport of selenium species in watershed simulated using a modified SWAT model.•The new model accounts for selenium transport in soils, aquifer, and streams.•Sensitivity analysis is used to identify controlling factors on selenium transport.•Hydrologic processes are the main control on selenium in agricultural watersheds.•Selenium mitigation procedures should focus on watershed water management.