Machine learning predictions of nitrate in groundwater used for drinking supply in the conterminous United States

Groundwater is an important source of drinking water supplies in the conterminous United State (CONUS), and presence of high nitrate concentrations may limit usability of groundwater in some areas because of the potential negative health effects. Prediction of locations of high nitrate groundwater i...

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Bibliographic Details
Published in:The Science of the total environment 2022-02, Vol.807 (Pt 3), p.151065-151065, Article 151065
Main Authors: Ransom, K.M., Nolan, B.T., Stackelberg, P.E., Belitz, K., Fram, M.S.
Format: Article
Language:English
Subjects:
Equivalent population
Groundwater
Groundwater contamination
Humans
Machine Learning
National Water Quality Assessment
Nitrates
Process-informed machine learning
Three-dimensional
United States
Water Supply
Water Wells
XGBoost
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Summary:Groundwater is an important source of drinking water supplies in the conterminous United State (CONUS), and presence of high nitrate concentrations may limit usability of groundwater in some areas because of the potential negative health effects. Prediction of locations of high nitrate groundwater is needed to focus mitigation and relief efforts. A three-dimensional extreme gradient boosting (XGB) machine learning model was developed to predict the distribution of nitrate. Nitrate was predicted at a 1 km resolution for two drinking water zones, each of variable depth, one for domestic supply and one for public supply. The model used measured nitrate concentrations from 12,082 wells and included predictor variables representing well characteristics, hydrologic conditions, soil type, geology, land use, climate, and nitrogen inputs. Predictor variables derived from empirical or numerical process-based models were also included to integrate information on controlling processes and conditions. The model provided accurate estimates at national and regional scales: the training (R2 of 0.83) and hold-out (R2 of 0.49) data fits compared favorably to previous studies. Predicted nitrate concentrations were less than 1 mg/L across most of the CONUS. Nationally, well depth, soil and climate characteristics, and the absence of developed land use were among the most influential explanatory factors. Only 1% of the area in either water supply zone had predicted nitrate concentrations greater than 10 mg/L; however, about 1.4 M people depend on groundwater for their drinking supplies in those areas. Predicted high concentrations of nitrate were most prevalent in the central CONUS. In areas of predicted high nitrate concentration, applied manure, farm fertilizer, and agricultural land use were influential predictor variables. This work represents the first application of XGB to a three-dimensional national-scale groundwater quality model and provides a significant milestone in the efforts to document nitrate in groundwater across the CONUS. [Display omitted] •High resolution machine learning model predicts national-scale groundwater nitrate.•Depth-varying prediction with emphasis on public and private drinking supply•SHAP analysis identifies drivers of nitrate at national and regional scales.•1.4M equivalent people depend on groundwater with high nitrate concentration.
ISSN:0048-9697
1879-1026
DOI:10.1016/j.scitotenv.2021.151065