Frontiers | Density structures of the upper mantle in the East African Rift System: implications for the evolution of intracontinental rifting

IF 2 3区地球科学 Q3 GEOSCIENCES, MULTIDISCIPLINARY

Frontiers in Earth Science Pub Date : 2024-07-29 DOI:10.3389/feart.2024.1425806

Wenfeng Tao, Qing Liang, Chao Chen

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Abstract

The East African Rift System (EARS) provides an ideal natural laboratory for studying the mechanisms of tectonic plate breakup and continental drift, as well as a unique perspective for exploring the maturation process of continental rifting and its drivers. This study combines high-resolution satellite gravity data and seismic tomography model with an integrated geophysical approach to reveal the density structures in the upper mantle of the EARS. The results show that the northeastern to central Congo and Zimbabwe Craton exhibit significant high-density anomalies extending up to 250 km, which is indicative of a thicker and more intact lithosphere. In contrast, the Uganda, Tanzania, eastern and southern Congo, and Kaapvaal Craton show shallow high-density anomalies underlain by low-density anomalies that are clearly derived from the deeper mantle, indicating a thining of the lithosphere with some degree of possible melting at the base. The various rift segments of the EARS exhibit different rift morphologies. The Main Ethiopian Rift and the Kenya Rift of the Eastern Rift Branch show strong low-density anomalies, indicating intense melting, which is much stronger than that observed in the Western Rift Branch. However, the two rifts may have originated from the same mantle uplift in which the low-density anomalies of the Eastern and Western Rift Branches connected in the deep upper mantle. The lower portion of the Malawi Rift exhibits weaker low-denstiy anomalies, which can be observed to the south of the Malawi Rift, extending further south as a continuation of the EARS. Combining the results of previous kinetics simulations and our density perturbation results, it can be inferred that the Eastern Rift Branch is mainly affected by active rifting, while the Western Rift Branch is affected by both active and passive rifting.

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前沿｜东非大裂谷系统上地幔的密度结构：对大陆内断裂演化的影响

东非裂谷系统（EARS）为研究构造板块断裂和大陆漂移机制提供了一个理想的天然实验室，也为探索大陆裂谷的成熟过程及其驱动因素提供了一个独特的视角。这项研究将高分辨率卫星重力数据和地震层析成像模型与综合地球物理方法相结合，揭示了 EARS 上地幔的密度结构。研究结果表明，刚果和津巴布韦克拉通东北部至中部呈现出明显的高密度异常，最长可达 250 公里，这表明岩石圈较厚且完整。相比之下，乌干达、坦桑尼亚、刚果东部和南部以及卡普瓦尔克拉通则显示出浅层高密度异常，其下是明显来自深层地幔的低密度异常，表明岩石圈变薄，底部可能存在一定程度的熔融。埃塞俄比亚断裂带的各个断裂段呈现出不同的断裂形态。东裂谷支流的埃塞俄比亚主裂谷和肯尼亚裂谷显示出强烈的低密度异常，表明熔化强烈，比在西裂谷支流观察到的熔化强烈得多。然而，这两条裂谷可能起源于同一次地幔隆起，在这次隆起中，东部裂谷支脉和西部裂谷支脉的低密度异常在深层上地幔中连接起来。马拉维大裂谷下部的低密度异常较弱，在马拉维大裂谷南部可以观察到低密度异常，并进一步向南延伸，成为 EARS 的延续。结合之前的动力学模拟结果和我们的密度扰动结果，可以推断东部裂谷支主要受到主动断裂的影响，而西部裂谷支则同时受到主动断裂和被动断裂的影响。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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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

期刊介绍： Frontiers in Earth Science is an open-access journal that aims to bring together and publish on a single platform the best research dedicated to our planet. This platform hosts the rapidly growing and continuously expanding domains in Earth Science, involving the lithosphere (including the geosciences spectrum), the hydrosphere (including marine geosciences and hydrology, complementing the existing Frontiers journal on Marine Science) and the atmosphere (including meteorology and climatology). As such, Frontiers in Earth Science focuses on the countless processes operating within and among the major spheres constituting our planet. In turn, the understanding of these processes provides the theoretical background to better use the available resources and to face the major environmental challenges (including earthquakes, tsunamis, eruptions, floods, landslides, climate changes, extreme meteorological events): this is where interdependent processes meet, requiring a holistic view to better live on and with our planet. The journal welcomes outstanding contributions in any domain of Earth Science. The open-access model developed by Frontiers offers a fast, efficient, timely and dynamic alternative to traditional publication formats. The journal has 20 specialty sections at the first tier, each acting as an independent journal with a full editorial board. The traditional peer-review process is adapted to guarantee fairness and efficiency using a thorough paperless process, with real-time author-reviewer-editor interactions, collaborative reviewer mandates to maximize quality, and reviewer disclosure after article acceptance. While maintaining a rigorous peer-review, this system allows for a process whereby accepted articles are published online on average 90 days after submission. General Commentary articles as well as Book Reviews in Frontiers in Earth Science are only accepted upon invitation.