在断裂-断裂-断裂三重交界处调和板块运动和断层作用

Geology Pub Date : 2024-02-23 DOI:10.1130/g51909.1
D. Maestrelli, Federico Sani, Derek Keir, C. Pagli, Alessandro La Rosa, A. Muluneh, Sascha Brune, G. Corti
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摘要

断裂-断裂-断裂三重交界处是三个板块相互作用的区域,产生了复杂的方向可变的断层网络。虽然断层网络的几何形状很容易从其地表表现中得到约束,但仍不清楚的是断层的运动学及其相互作用在空间上是如何变化的,以及这些变化与三个板块相互分离所产生的异常地壳运动之间的关系。阿法尔凹陷位于非洲板块、阿拉伯板块和索马里板块(位于非洲之角)的三重交界处,在这里,结构测绘、地震和全球导航卫星系统(GNSS)等观测数据的独特组合使我们能够了解断层运动学与板块运动之间的联系。我们用一个模拟模型来补充这些观测数据,以深入了解断层的形态和方向与整个板块运动之间的关系。模型和自然界的一个关键发现是,一些相邻的正断层以高角度形成,并产生 T 形结构。这些纯正的正断层是同步活动的,这意味着延伸方向在局部变化了90°。尽管整体地表运动模式相对平滑,但我们的模型和自然界中的这些运动对比还是出现了。结果表明,以高角度相互作用形成 T 形结构的正断层可以在几千米范围内的应力场中同步演化,应力场的大小变化平缓,但方向变化剧烈。
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Reconciling plate motion and faulting at a rift-rift-rift triple junction
Rift-Rift-Rift triple junctions are regions where three plates interact, generating complex networks of variably oriented faults. While the geometry of the fault networks is easily constrained from their surface expression, what remains unclear is how the kinematics of faults and their interactions vary spatially, and how these relate to the unusual crustal motions that result from three plates diverging from each other. The Afar depression lies at the triple junction between the African, Arabian, and Somalian plates (in the Horn of Africa), where the unique combination of observational data from structural mapping, seismicity, and Global Navigation Satellite System (GNSS) allows us to understand the link between fault kinematics and plate motions. We complement these observations with an analog model to gain insights into how the patterns and directions of faults relate to overall plate motions. A key finding in both the model and nature is that some adjacent normal faults form at high angles and generate T-shaped structures. These purely normal faults are synchronously active, which means that the extension direction varies ∼90° locally. These kinematic contrasts in our model and in nature occur despite the relatively smooth pattern of overall surface motions. The results indicate that normal faults interacting at high angles to form the T-shaped structures can evolve synchronously within a stress field that varies gently in magnitude but dramatically in orientation over a few kilometers.
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