Abstract
Agricultural months are the critical period for the allocation of surface water and groundwater resources due to the increased demands on water supplies and decreased recharge rate. This situation urges the necessity of using conjunctive water management to fulfill the entire water demand. Here, we proposed an approach for aquifer stabilization and meeting the maximum water demand based on the available surface and groundwater resources and their limitations. In this approach, we first used the MODFLOW model to simulate the groundwater level to control the optimal withdrawal and the resulting drop. We next used a whale optimization algorithm (WOA) to develop an optimized model for the planning of conjunctive use to minimize the monthly water shortage. In the final step, we incorporated the results of the optimized conjunctive model and the available field data into the least squares-support vector machine (LS-SVM) model to predict the amounts of water shortage for each month, particularly for the agricultural months. The results showed that during the period from 2005 to 2020, the most water shortage belonged to 2018, in which only about 52% of water demand was met with the contribution of groundwater (67%) and surface water (33%). However, the groundwater level could have increased by about 0.7 m during the study period by implementing the optimized model. The results of the third part revealed that LS-SVM could predict the water shortage with better performance with a root-mean-square error (RMSE), mean absolute percentage error (MAPE), and Nash–Sutcliffe Index of 5.70 m, 3.43%, and 0.89 m, respectively. The findings of this study will enable managers to predict the water shortage in future periods to make more informed decisions for water resource allocation.
Highlights
Included all input variables, was selected as the most appropriate model to predict the amount of monthly water shortage with an root-mean-square error (RMSE), mean absolute percentage error (MAPE), and Nash–Sutcliffe Index (NSE) of 5.70 million cubic meters (MCM), 3.43
The optimization model was applied to 12 months scenario, RMSE, MAPE, and NSE were 21.93 MCM, 13.65 MCM, and 0.58, respectively, of the 16 year period, and the amount of water shortage in each month was estimated
The sixth scenario, which included all input variables, was selected as the most appropriate model to predict the amount of monthly water shortage with an RMSE, MAPE, and NSE of 5.70 MCM, 3.43 MCM, and
Summary
Due to the scarcity of water supplies in many regions worldwide, and the potential changes in rainfall trends due to climate change [1–3], water withdrawal and consumption should be carefully managed. Given society’s desire to develop products that are in demand and to provide maximum profit, water supplies have diminished at an alarming rate [4,5]. The loss of freshwater and groundwater resources, depletion of aquifers, water stress and scarcity, land degradation, and desertification are some of the consequences of inappropriate water management around much of the world [6,7]. The 2018 edition of the Sustainability 2022, 14, 2691.
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