Abstract
The city of Essaouira is located along the north-west coast of Morocco, where groundwater is the main source of drinking, domestic and agricultural water. In recent decades, the salinity of groundwater has increased, which is why geochemical techniques and environmental isotopes have been used to determine the main sources of groundwater recharge and salinization. The hydrochemical study shows that for the years 1995, 2007, 2016 and 2019, the chemical composition of groundwater in the study area consists of HCO3–Ca–Mg, Cl–Ca–Mg, SO4–Ca and Cl–Na chemical facies. The results show that from 1995 to 2019, electrical conductivity increased and that could be explained by a decrease in annual rainfall in relation to climate change and water–rock interaction processes. Geochemical and environmental isotope data show that the main geochemical mechanisms controlling the hydrochemical evolution of groundwater in the Cenomanian–Turonian aquifer are the water–rock interaction and the cation exchange process. The diagram of δ2H = 8 * δ18O + 10 shows that the isotopic contents are close or above to the Global Meteoric Water Line, which suggests that the aquifer is recharged by precipitation of Atlantic origin. In conclusion, groundwater withdrawal should be well controlled to prevent groundwater salinization and further intrusion of seawater due to the lack of annual groundwater recharge in the Essaouira region.
Highlights
In most of the arid and semiarid regions of the world, the availability of sufficient freshwater has become a factor limiting growth [1,2,3]
Like other basins in coastal areas [30], the Essaouira basin has not been spared the effect of climate change, which is added to the effect of the overexploitation of groundwater
The socio-economic development in the Essaouira basin depends heavily on groundwater resource; the hydrochemical and isotopic studies made in this article aim to assess the process of salinization and recharge of the Plio-quaternary aquifer and Cenomano-Turonian aquifer given its strategic importance in the study area
Summary
In most of the arid and semiarid regions of the world, the availability of sufficient freshwater has become a factor limiting growth [1,2,3]. The geochemistry of groundwater in coastal aquifers represents previous geological conditions and current anthropogenic processes that affect the quality of groundwater [7,8,9,10]. The local and regional meaning of these aquifers, the key hydrogeological trends, hydrochemical characteristics and groundwater origins remain poorly known [11,12,13]. The combination of geochemistry and isotopic tools can lead to relevant information on the origin of mineralization of karst water [14,15,16,17].
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