Improving crop-specific groundwater use estimation in the Mississippi Alluvial Plain: Implications for integrated remote sensing and machine learning approaches in data-scarce regions

Sayantan Majumdar; Ryan Smith; Md Fahim Hasan; Jordan Wilson; Vincent E. White; Emilia L. Bristow; James R. Rigby; Wade Kress; Jaime A. Painter

doi:10.1016/j.ejrh.2024.101674

Improving crop-specific groundwater use estimation in the Mississippi Alluvial Plain: Implications for integrated remote sensing and machine learning approaches in data-scarce regions

Journal of Hydrology Regional Studies

By: Sayantan Majumdar, Ryan Smith, Md Fahim Hasan, Jordan Wilson, Vincent E. White, Emilia L. Bristow, James R. Rigby, Wade Kress, and Jaime A. Painter

https://doi.org/10.1016/j.ejrh.2024.101674

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Abstract

Study region

The Mississippi Alluvial Plain (MAP) in the United States (US).

Study focus

Understanding local-scale groundwater use, a critical component of the water budget, is necessary for implementing sustainable water management practices. The MAP is one of the most productive agricultural regions in the US and extracts more than 11 km³/year for irrigation activities. Consequently, groundwater-level declines in the MAP region pose a substantial challenge to water sustainability, and hence, we need reliable groundwater pumping monitoring solutions to manage this resource appropriately.

New hydrological insights for the region

We incorporate remote sensing datasets and machine learning to improve an existing lookup table-based model of groundwater use previously developed by the U.S. Geological Survey (USGS). Here, we employ Distributed Random Forests, an ensemble machine learning algorithm to predict annual and monthly groundwater use (2014–2020) throughout this region at 1-km resolution, using pumping data from existing flowmeters in the Mississippi Delta. Our model compares favorably with the existing USGS model, with higher R² (0.51 compared to 0.42 in the previous model), and lower root mean square error (RMSE) and mean absolute error (MAE)— 0.14 m and 0.09 m, respectively in our model, compared to 0.15 m and 0.1 m in the previous model. Therefore, this work advances our ability to predict groundwater use in regions with scarce or limited in-situ groundwater withdrawal data availability.

Study Area

Additional publication details
Publication type	Article
Publication Subtype	Journal Article
Title	Improving crop-specific groundwater use estimation in the Mississippi Alluvial Plain: Implications for integrated remote sensing and machine learning approaches in data-scarce regions
Series title	Journal of Hydrology Regional Studies
DOI	10.1016/j.ejrh.2024.101674
Volume	52
Year Published	2024
Language	English
Publisher	Elsevier
Contributing office(s)	Louisiana Water Science Center, Lower Mississippi-Gulf Water Science Center, Central Midwest Water Science Center
Description	101674, 38 p.
Country	United States
Google Analytic Metrics	Metrics page