Abstract
Abstract. Groundwater is crucial for domestic supplies in the Sahel, where the strategic importance of aquifers will increase in the coming years due to climate change. Groundwater potential mapping is a valuable tool to underpin water management in the region and, hence, to improve drinking water access. This paper presents a machine learning method to map groundwater potential. This is illustrated through its application in two administrative regions of Mali. A set of explanatory variables for the presence of groundwater is developed first. Scaling methods (standardization, normalization, maximum absolute value and max–min scaling) are used to avoid the pitfalls associated with reclassification. Noisy, collinear and counterproductive variables are identified and excluded from the input dataset. A total of 20 machine learning classifiers are then trained and tested on a large borehole database (n=3345) in order to find meaningful correlations between the presence or absence of groundwater and the explanatory variables. Maximum absolute value and standardization proved the most efficient scaling techniques, while tree-based algorithms (accuracy >0.85) consistently outperformed other classifiers. The borehole flow rate data were then used to calibrate the results beyond standard machine learning metrics, thereby adding robustness to the predictions. The southern part of the study area presents the better groundwater prospect, which is consistent with the geological and climatic setting. Outcomes lead to three major conclusions: (1) picking the best performers out of a large number of machine learning classifiers is recommended as a good methodological practice, (2) standard machine learning metrics should be complemented with additional hydrogeological indicators whenever possible and (3) variable scaling contributes to minimize expert bias.
Highlights
Today, 2.5 billion people across the world depend on groundwater for domestic supply (Grönwall and Danert, 2020)
Groundwater is crucial in arid regions, such as the Sahel, where aquifers provide a permanent source of good-quality water during the months of the year in which rainfall and surface water are absent (Llamas and Martínez-Santos, 2005; Díaz-Alcaide et al, 2017)
There is no hard threshold as to what is an acceptable level of correlation between two variables, the literature shows that values between 0.4 and 0.85 may be acceptable (Dormann et al, 2013)
Summary
2.5 billion people across the world depend on groundwater for domestic supply (Grönwall and Danert, 2020). In a context of climate change, with rainfall expected to decrease and droughts likely to become more intense (Arneth et al, 2019), groundwater resources will be increasingly relied upon. This could well be the case in rural Mali, where access to drinking water and sanitation is a concern. In 2017, only 68 % of the rural population had “at least basic” drinking water access, while 24 % relied on unimproved water sources like unprotected springs and wells (UNICEF/WHO, 2019). Groundwater potential mapping (GPM) is recognized as a valuable tool to underpin the planning and exploration of groundwater resources (Elbeih, 2015).
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