Abstract
Managed aquifer recharge and changes in crop type or nutrient management on agricultural lands are promising approaches to address groundwater quality degradation by nitrate. Tools to assess nonpoint-source contaminant transport are needed to better understand the interaction between agricultural management practices and long-term nitrate dynamics in groundwater basins. This study investigates the impact of time-resolution upscaling of groundwater flow stresses (i.e., recharge, pumping, and evapotranspiration rates) on the long-term prediction of nitrate transport at the regional scale. A three-dimensional, monthly transient flow and nitrate-transport model using MODFLOW and MT3D is applied as the reference simulation. The reference model results are compared to temporally upscaled models with (1) upscaled annual-averaged flow and transport stresses and (2) steady-state flow stresses, across different management scenarios. Models with annual-averaged flow and nitrate-loading stresses were found to be the best alternative to the reference model. However, employing a steady-state flow field to parameterize transient transport models, using a time series of spatially variable annual total contaminant loading, provides a useful alternative to predict the trend and variability of nitrate-concentration breakthrough curves at wells across the regional scale and to differentiate the effects of various agricultural management scenarios, if the history of the source contaminant mass is known. The difference between concentrations resulting from steady-state-flow versus transient-flow models is less than 2 mgN/L for nearly 75% of shallow groundwater cells in the model. However, the steady-state-flow-model-based transport simulation does not capture short-term oscillations of nitrate concentrations in pumping wells at the local scale.
Highlights
Failure to preserve clean groundwater is of growing concern due to the important role of groundwater as a source of drinking water worldwide
The nitrate contamination problem can be addressed in the long run by managing pollutant sources, while different strategies have been introduced in the short term to remove or attenuate nitrate in drinking water pumped from aquifers (Jensen et al 2012)
Temporal dynamics of shallow groundwater nitrate in the reference (BAU) case is mainly controlled by the time-variant heterogeneity of the land use in the region
Summary
Failure to preserve clean groundwater is of growing concern due to the important role of groundwater as a source of drinking water worldwide. Different sources of nitrate pollution are distributed continuously across landscapes (nonpoint-source groundwater contamination) and nitrate in rural regions originates mainly from agricultural activities (Dalgaard et al 2014; Harter et al 2017; King et al 2012; Van Grieken et al 2019). The nitrate contamination problem can be addressed in the long run by managing pollutant sources, while different strategies have been introduced in the short term to remove or attenuate nitrate in drinking water pumped from aquifers (Jensen et al 2012). Regulators, policy- and decision-makers, the public, and the regulated agricultural community want to understand the feasibility of long-term improvements in groundwater quality that can be achieved with a range of Hydrogeol J (2020) 28:1299–1322 source management practices with respect to an ensemble of domestic and public water supply wells in a particular aquifer system of concern. Designed simulation models are needed to assess the impact of promising irrigation-, nutrient-, and recharge-management practices on long-term distributed groundwater quality (Fogg and LaBolle 2006)
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