The legacy of the East African rift system in understanding continental rifts worldwide from geophysical studies (with emphasis on gravity and magnetic studies)

IF 2.2 4区地球科学 Q2 GEOSCIENCES, MULTIDISCIPLINARY

Journal of African Earth Sciences Pub Date : 2025-02-22 DOI:10.1016/j.jafrearsci.2025.105589

Luelseged Emishaw , Andrew Katumwehe , Khumo Leseane , Zelalem Demissie , Kevin Mickus , Mohamed Abdelsalam

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Abstract

The diverse geology of the African continent has provided the geoscientific community with an unparallel opportunity to examine and understand complex endogenic and exogenic processes that have shaped and are still shaping our Planet Earth. An exemplary illustration of this is the East African Rift System (EARS), which traverses the African continent from its northeastern part in the Afar Depression to its southern part in the Okavango Rift Zone. In this review, we aim to provide an overview of the notable gravity and magnetic studies that have contributed to our understanding of continental rift evolution. Our primary focus is on gravity and magnetic contributions to understanding the rifting processes from their enigmatic nucleation as incipient rift systems to their subsequent progression from continental rifting to seafloor spreading, an aspect that garnered more attention and investigation. We highlight the legacy of gravity and magnetic studies in understanding the evolution of continental rifts from eight studies starting from the most evolved segment of the EARS in the Afar Depression to the most incipient segment of the rift in the Okavango Rift Zone. These include: (1) The transitioning from continental rifting to seafloor spreading in the Afar Depression (The Tendaho graben). (2) Nucleation of a future divergent plate boundary within an overlapping propagating embryonic spreading center (The Dobi graben). (3) Transfer of extension from rift border faults to rift floor through magma-assisted rifting (The Main Ethiopian Rift). (4) The evolution of broadly rifted zones though upwelling of mantle flow resulting in an unstable dynamic topography and subsequent gravitational collapse (The Southern Main Ethiopian Rift). (5) Three-dimensional (3D) crustal density stratification and superimposed rifting events (The Turkana rifted zone). (6) The rifting of cratons that is facilitated by inherited zones of weakness presented by orogenic belts (The Eyasi basin). (7) The role of preexisting lithospheric structures in controlling continental rift evolution (The Albertine – Rhino graben). (8) The role of fluid concentration through lithospheric zones of weakness in continental rift initiation (The Okavango Rift Zone).

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非洲大陆多样的地质为地球科学界提供了一个无与伦比的机会，来研究和了解复杂的内源和外源过程，这些过程已经并仍在塑造着我们的地球。东非大裂谷系统（EARS）就是这方面的一个典范，它横贯非洲大陆，从东北部的阿法尔洼地一直延伸到南部的奥卡万戈大裂谷区。在本综述中，我们旨在概述有助于我们了解大陆裂谷演变的著名重力和磁力研究。我们的主要重点是重力和磁力对了解断裂过程所做的贡献，这些过程包括断裂系统作为初生断裂系统的神秘成核过程，以及随后从大陆断裂到海底扩张的发展过程（这是一个获得更多关注和研究的方面）。我们重点介绍了重力和磁力研究在了解大陆裂谷演变方面的遗产，从阿法尔凹陷的 EARS 最演化区段到奥卡万戈裂谷带的裂谷最萌芽区段的八项研究开始。这些研究包括(1) 阿法尔凹陷从大陆断裂向海底扩张的过渡（坦达霍地堑）。(2) 在重叠传播的胚胎扩张中心（多比地堑）内形成未来的板块分异边界。(3) 通过岩浆辅助断裂，从裂谷边界断层向裂谷底延伸（埃塞俄比亚主裂谷）。(4) 通过地幔流的上涌导致不稳定的动态地形和随后的重力塌陷（埃塞俄比亚南部主裂谷），形成宽阔的裂谷带。(5) 三维地壳密度分层和叠加断裂事件（图尔卡纳断裂带）。(6) 造山带遗留的薄弱带促进了板块的断裂（埃亚西盆地）。(7) 预先存在的岩石圈结构在控制大陆裂谷演变中的作用（阿尔贝蒂娜-犀牛地堑）。(8) 流体通过岩石圈薄弱带的聚集在大陆裂谷形成中的作用（奥卡万戈裂谷带）。

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来源期刊

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

CiteScore

4.70

自引率

4.30%

发文量

240

审稿时长

12 months

期刊介绍： The Journal of African Earth Sciences sees itself as the prime geological journal for all aspects of the Earth Sciences about the African plate. Papers dealing with peripheral areas are welcome if they demonstrate a tight link with Africa. The Journal publishes high quality, peer-reviewed scientific papers. It is devoted primarily to research papers but short communications relating to new developments of broad interest, reviews and book reviews will also be considered. Papers must have international appeal and should present work of more regional than local significance and dealing with well identified and justified scientific questions. Specialised technical papers, analytical or exploration reports must be avoided. Papers on applied geology should preferably be linked to such core disciplines and must be addressed to a more general geoscientific audience.