Integrating facies, mineralogy, and paleomagnetism to constrain the age and provenance of Paleozoic siliciclastic sedimentary rocks along the northern Gondwana margin: insights from the Araba and Naqus formations in western Gulf of Suez, Egypt

IF 1.8 3区地球科学 Q3 GEOSCIENCES, MULTIDISCIPLINARY

International Journal of Earth Sciences Pub Date : 2024-04-18 DOI:10.1007/s00531-024-02405-x

Ashraf M. Al-Nashar, Nabil A. Abdel Hafez, Mohamed W. Abd El-Moghny, Ahmed Awad, Sherif Farouk, Haitham M. Ayyad

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Abstract

The depositional ages and provenance of the Paleozoic Araba and Naqus Formations along the northern Gondwanan margin in Egypt have remained uncertain due to a lack of index fossils. Resolving this issue is crucial for understanding regional geology during deposition and subsequent tectonic development. We integrate detailed facies analysis, anisotropy of magnetic susceptibility (AMS), paleomagnetism, and mineralogical data to elucidate the genesis and depositional ages of the Araba and Naqus Formations. Petrographic analyses identified seven distinct facies types, providing insights into sedimentary textures, maturity, and sources, with contributions from igneous and metamorphic sources indicated by heavy minerals. X-ray diffraction (XRD) analysis identified accessory minerals such as quartz, goethite, kaolinite, hematite, and anatase. Paleomagnetism isolated two magnetic components (C_A and C_N) providing the first robust paleo pole positions at Lat. = 70.8° N, Long. = 308.2° E and Lat. = 37.8° N, Long. = 233.1° E, indicating Cambrian and Carboniferous ages for the Araba and Naqus formations, respectively. Thermal demagnetization constrained these dates using established polarity timescales. Mineralogical data indicated that the Araba Formation originated from an igneous source, while the Naqus Formation had a mixed metamorphic-igneous provenance. The integrated AMS and paleomagnetic data reveal evidence of post-depositional deformation. Specifically, the clustering of maximum AMS axes in the NW–SE direction for both formations, suggests the initial presence of a primary depositional fabric. However, prevalent tectonic activity during the Cenozoic appears to have overprinted and modified this fabric through deformation related to rifting of the Gulf of Suez region. Through this novel multi-proxy approach, we have resolved long-standing uncertainties regarding the formations' depositional ages. Our study thereby provides the first chronostratigraphic framework for these strategically important sedimentary units, significantly advancing understanding of regional Paleozoic geology.

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整合岩相、矿物学和古地磁学，制约冈瓦纳大陆北缘古生代硅质沉积岩的年龄和产地：埃及苏伊士湾西部阿拉巴和纳库斯地层的启示

由于缺乏索引化石，埃及冈瓦纳山脉北缘古生代阿拉巴地层和纳库斯地层的沉积年龄和出处一直不确定。解决这一问题对于了解沉积过程中的区域地质以及随后的构造发展至关重要。我们整合了详细的岩相分析、磁感应强度各向异性（AMS）、古地磁学和矿物学数据，以阐明阿拉巴地层和纳库斯地层的成因和沉积年代。岩相分析确定了七种不同的岩相类型，提供了有关沉积质地、成熟度和来源的见解，重矿物显示了火成岩和变质岩的来源。X 射线衍射（XRD）分析确定了石英、网纹石、高岭石、赤铁矿和锐钛矿等附属矿物。古地磁学分离出两个磁性成分（CA 和 CN），首次在北纬 = 70.8°、东经 = 308.2°和北纬 = 37.8°、东经 = 233.1°提供了可靠的古磁极位置，分别表明了阿拉巴地层和纳库斯地层的寒武纪和石炭纪年龄。热消磁法利用已确定的极性时间尺度对这些日期进行了约束。矿物学数据表明，阿拉巴地层源于火成岩，而纳库斯地层则源于变质岩和火成岩混合地层。综合 AMS 和古地磁数据揭示了沉积后变形的证据。具体地说，两个地层的最大 AMS 轴都集中在西北-东南方向，这表明最初存在原生沉积结构。然而，新生代的普遍构造活动似乎通过与苏伊士湾地区断裂有关的变形对这一结构进行了覆盖和修改。通过这种新颖的多代理方法，我们解决了有关地层沉积年龄的长期不确定性。因此，我们的研究为这些具有重要战略意义的沉积单元提供了第一个年代地层学框架，极大地促进了对区域古生代地质学的了解。

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来源期刊

International Journal of Earth Sciences 地学-地球科学综合

CiteScore

4.60

自引率

4.30%

发文量

120

审稿时长

4-8 weeks

期刊介绍： The International Journal of Earth Sciences publishes process-oriented original and review papers on the history of the earth, including - Dynamics of the lithosphere - Tectonics and volcanology - Sedimentology - Evolution of life - Marine and continental ecosystems - Global dynamics of physicochemical cycles - Mineral deposits and hydrocarbons - Surface processes.