利用遥感和航磁数据在埃及上苏哈格省绘制基于综合方法的地下水图

IF 2 3区地球科学 Q3 GEOSCIENCES, MULTIDISCIPLINARY

Frontiers in Earth Science Pub Date : 2024-09-12 DOI:10.3389/feart.2024.1456055

Hussein T. El-Badrawy, Abbas M. Abbas, Usama Massoud, Tamer Abu-Alam, Hamed A. Alrefaee, Saif M. Abo Khashaba, Mostafa Nagy

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引用次数: 0

摘要

引言由于城市的快速发展，地下水需求大大增加，特别是在主要依赖地下水的干旱地区。本研究旨在利用遥感和航磁数据，结合基于层次分析法（AHP）的地理信息系统，评估埃及索哈格地区的潜在地下水区。方法利用各种遥感数据集开发了九个专题图层，包括土壤湿度、降雨量、岩性、归一化差异植被指数（NDVI）、排水密度、线状密度、坡度和土地利用/土地覆盖。除遥感衍生专题图层外，还包括由 RTP 航空磁图代表的地球物理衍生专题图层。通过分析和解释气磁数据，勾勒出影响地下水储存和流动的地下结构。此外，航磁数据分析还有助于估算构成努比亚含水层基底的基底深度，并确定具有相当厚的沉积矿床和大量储水的区域。最有希望的地点集中在尼罗河谷沿线以及研究区域的西北部和东北部。研究结果表明，主要的磁性构造趋势为西北-东南、东北-西南、北-南和东-西，这促成了一系列地表下地角（H）和地堑（G）的形成。三个主要盆地（A、B 和 C）被确定为最深的区域。这些盆地代表了最有潜力的地下水积聚区，对未来的水文地质勘探具有吸引力。这种综合方法为协助制定适当的干旱地区地下水管理计划提供了强有力的有效工具。

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Integrated approach-based groundwater mapping in sohag governorate, upper Egypt, using remote sensing and aeromagnetic data

IntroductionGroundwater demand has been considerably heightened due to rapid urban growth, specifically in arid areas that rely primarily on groundwater. This study aims to utilize remote sensing and aeromagnetic data, combined with the Analytic Hierarchy Process (AHP) based GIS, to evaluate potential groundwater zones in the Sohag area, Egypt.MethodsNine thematic layers, including soil moisture, rainfall, lithology, normalized difference vegetation index (NDVI), drainage density, lineament density, slope, and land use/land cover, were developed using various remote sensing datasets. Besides the remote sensing-derived thematic layers, a geophysics-derived thematic layer represented by the RTP aeromagnetic map was included. The aeromagnetic data were analyzed and interpreted to outline the subsurface structure affecting groundwater storage and flow. Also, the aeromagnetic data analysis helps estimate the basement depth that constitutes the Nubian Aquifer’s base and identifies regions with considerable thick sedimentary deposits and significant water reserves.Results and discussionThe groundwater potentiality map was consistent with production wells in the area, and sites for drilling new wells were predicted, especially in the Nile Valley around the Tahta, El-Hamimia, and west Sohag cities. The most promising sites are clustered along the Nile Valley, and the study area’s northwestern and northeastern parts. The results indicate that the predominant magnetic structural trends are NW-SE, NE-SW, N-S, and E-W, which contribute to the formation of a series of subsurface horsts (H) and grabens (G). Three main basins (A, B, and C) were identified as the most profound areas. These basins represent the most promising areas for groundwater accumulation, making them attractive for future hydrogeological exploration. This integrated approach strongly offers a powerful and effective tool to assist in developing an appropriate plan to manage groundwater in arid regions.

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来源期刊

Frontiers in Earth Science Earth and Planetary Sciences-General Earth and Planetary Sciences

CiteScore

3.50

自引率

10.30%

发文量

2076

审稿时长

12 weeks

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