MDPI - Water: "Machine Learning Models for Mapping Groundwater Pollution Risk: Advancing Water Security and Sustainable Development Goals in Georgia, USA."
Shivank Pandey 1, Srimanti Duttagupta 2,* and Avishek Dutta 2,3,*
1 Department of Computer Science, University of Georgia, Athens, GA 30602, USA; shivank.pandey@uga.edu
2 Department of Geology, University of Georgia, Athens, GA 30602, USA
3 Savannah River Ecological Laboratory, University of Georgia, Aikens, SC 29802, USA
* Correspondence: sduttagupta@uga.edu (S.D.); avishek.dutta@uga.edu (A.D.)
The study provides valuable insights into predicting pesticide contamination in groundwater using machine learning and aligns with the Georgia First mission, in which our department is actively involved.
Abstract:
The widespread use of pesticides, such as atrazine and malathion, in agricultural systems raises significant concerns regarding the contamination of groundwater, which serves as a critical resource for drinking water. This study applies machine learning techniques to predict the concentrations of atrazine and malathion in groundwater across Georgia, USA, using 2019 data. A Random Forest classifier was employed to integrate various environmental and demographic factors, including pesticide application rates, precipitation, lithology, and population density, to predict pesticide contamination in groundwater. The models demonstrated high training accuracies of 100% and moderate average testing accuracy of 55% for atrazine and 60% for malathion across five iterations. The low test accuracy of the model, ranging from 50% to 75%, is likely due to overfitting, which can be attributed to the small dataset size and the complex nature of pesticide-contamination patterns, making it challenging for the model to generalize to unseen data. Feature importance analysis revealed that average pesticide usage emerged as the most influential factor for atrazine, while aquifer lithology and precipitation played crucial roles in both models. These results provide valuable insights into the dynamics of pesticide contamination, highlighting areas at greater risk of contamination. The findings underscore the importance of integrating environmental, geological, and agricultural variables for more effective groundwater management and sustainable agricultural practices, contributing to the protection of water resources and public health.