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沙特阿拉伯东部卡提夫地区沿海含水层海水入侵的水文地质、水化学和同位素综合评估。

Integrated Hydrogeological, Hydrochemical, and Isotopic Assessment of Seawater Intrusion into Coastal Aquifers in Al-Qatif Area, Eastern Saudi Arabia.

机构信息

Interdisciplinary Research Center for Membranes and Water Security, King Fahd University of Petroleum and Minerals, Dhahran 31261, Saudi Arabia.

Geosciences Department, College of Petroleum Engineering & Geosciences, King Fahd University of Petroleum & Minerals (KFUPM), Dhahran 31261, Saudi Arabia.

出版信息

Molecules. 2022 Oct 12;27(20):6841. doi: 10.3390/molecules27206841.

DOI:10.3390/molecules27206841
PMID:36296433
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9609279/
Abstract

Seawater intrusion (SWI) is the main threat to fresh groundwater (GW) resources in coastal regions worldwide. Early identification and delineation of such threats can help decision-makers plan for suitable management measures to protect water resources for coastal communities. This study assesses seawater intrusion (SWI) and GW salinization of the shallow and deep coastal aquifers in the Al-Qatif area, in the eastern region of Saudi Arabia. Field hydrogeological and hydrochemical investigations coupled with laboratory-based hydrochemical and isotopic analyses (O and H) were used in this integrated study. Hydrochemical facies diagrams, ionic ratio diagrams, and spatial distribution maps of GW physical and chemical parameters (EC, TDS, Cl, Br), and seawater fraction () were generated to depict the lateral extent of SWI. Hydrochemical facies diagrams were mainly used for GW salinization source identification. The results show that the shallow GW is of brackish and saline types with EC, TDS, Cl, Br concentration, and an increasing trend seaward, indicating more influence of SWI on shallow GW wells located close to the shoreline. On the contrary, deep GW shows low and EC, TDS, Cl, and Br, indicating less influence of SWI on GW chemistry. Moreover, the shallow GW is enriched in O and H isotopes compared with the deep GW, which reveals mixing with recent water. In conclusion, the reduction in GW abstraction in the central part of the study area raised the average GW level by three meters. Therefore, to protect the deep GW from SWI and salinity pollution, it is recommended to implement such management practices in the entire region. In addition, continuous monitoring of deep GW is recommended to provide decision-makers with sufficient data to plan for the protection of coastal freshwater resources.

摘要

海水入侵(SWI)是世界沿海地区淡水资源的主要威胁。及早识别和划定此类威胁有助于决策者规划适当的管理措施,以保护沿海社区的水资源。本研究评估了沙特阿拉伯东部地区 Al-Qatif 地区浅部和深部沿海含水层的海水入侵(SWI)和地下水咸化。本综合研究结合了现场水文地质和水化学调查以及基于实验室的水化学和同位素分析(O 和 H)。生成了地下水物理和化学参数(EC、TDS、Cl、Br)和海水分数的水化学相图、离子比图以及空间分布图,以描绘 SWI 的侧向范围。水化学相图主要用于确定地下水咸化的来源。结果表明,浅层地下水为微咸水和咸水类型,EC、TDS、Cl、Br 浓度呈增加趋势,表明靠近海岸线的浅层地下水井受到 SWI 的影响更大。相反,深部地下水的 较低,EC、TDS、Cl 和 Br 较低,表明 SWI 对地下水化学的影响较小。此外,浅层地下水的 O 和 H 同位素比深部地下水丰富,表明与近期水混合。总之,研究区中部地下水开采量的减少使地下水平均水位升高了三米。因此,为了保护深部地下水免受 SWI 和盐污染的影响,建议在整个地区实施此类管理措施。此外,建议对深部地下水进行连续监测,为决策者提供足够的数据,以规划沿海淡水资源的保护。

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