Dynamic evolution of competing same-dip double subduction: New perspectives of the Neo-Tethyan plate tectonics

IF 4.8 1区 地球科学 Q1 GEOCHEMISTRY & GEOPHYSICS
Arnab Roy , Nibir Mandal , Jeroen Van Hunen
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引用次数: 0

Abstract

Same-dip double-subduction (SDDS) systems are widely reported from present as well as past complex convergent plate tectonic configurations. However, the dynamics of their evolution is poorly understood, which is crucial to conceptualize anomalous subducting slab kinematics and associated observed geological phenomena, such as irregular trench migration rates, high convergence velocities, and slab break-off. To bridge this gap, we develop dynamic thermo-mechanical subduction models and investigate the initiation and evolution of SDDS systems, considering three different initial plate configurations: oceanic, oceanic-continental and multiple continental settings, based on Neo-Tethyan paleo-reconstructions. Each model offers new insights into the complex tectonic history of the major Neo-Tethyan subduction zones, particularly the Indo–Eurasian and Andaman convergent systems. We evaluate the slab-slab interactions, trench and subduction kinematics, inter-plate reorganization, and temporally varying mantle flow patterns involved in the dynamic evolution of these SDDS systems. The oceanic SDDS model simulations reveal that a sizable oceanic plate can initiate two subduction zones synchronously, and they evolve unequally in a competing mode, leading to exceptionally high convergence rates (∼16–17 cm/year) for a prolonged duration (∼7–8 Myr). This finding explains the coeval activity of coupled subduction zones in the Indo-Eurasia convergence during the Cretaceous evolution of the Neo-Tethys. We further implement a corresponding single subduction model to assess the additional effects of competing slab kinematics in an oceanic SDDS setting. The ocean-continent SDDS model, on the other hand, localizes subduction preferentially at passive margins between the oceanic plate and the continental block, forming double subduction zones that grow almost equally to form a spreading centre between the two trenches. These model results allow to reconstruct the Cenozoic evolution of the eastern Neo-Tethyan region, which ultimately led to the development of the Andaman subduction zone. We also show the post-Cretaceous evolution of the Indo–Eurasian collision zone as a consequence of the SDDS dynamics in presence of multiple continental blocks. These dynamics facilitated slab break-off, transforming the SDDS into a single subduction system in a relatively short time frame (∼3 Myr). We finish with a synthesis of the paleo-reconstructions of the Neo-Tethys in the perspective of these SDDS models.
竞争性同斜双俯冲的动态演化:新泰西期板块构造的新视角
同位双俯冲(SDDS)系统在现在和过去的复杂会聚板块构造中被广泛报道。然而,人们对它们的动力学演化却知之甚少,而这对于理解异常俯冲板块运动学和相关的观测到的地质现象(如不规则海沟迁移率、高会聚速度和板块断裂)至关重要。为了弥补这一差距,我们建立了动态热机械俯冲模型,并基于新太古宙古构造,考虑了三种不同的初始板块构造:大洋型、大洋-大陆型和多大陆型,研究了SDDS系统的起始和演化。每个模型都为了解主要新紫陶纪俯冲带(尤其是印度-欧亚大陆和安达曼汇聚系统)的复杂构造历史提供了新的视角。我们评估了板块与板块之间的相互作用、海沟和俯冲运动学、板块间重组以及这些特大深潜系统动态演化过程中所涉及的随时间变化的地幔流动模式。大洋SDDS模型模拟显示,一个相当大的大洋板块可以同步启动两个俯冲带,并且它们以竞争模式不平等地演化,从而导致长时间(7-8 Myr)的超高辐合率(16-17厘米/年)。这一发现解释了在新特提斯白垩纪演化过程中,印度-欧亚大陆会聚中耦合俯冲带的共时活动。我们进一步建立了一个相应的单一俯冲模型,以评估在大洋-大陆SDDS环境中板块运动学竞争的额外影响。另一方面,大洋-大陆SDDS模型将俯冲优先定位在大洋板块和大陆块之间的被动边缘,形成双俯冲带,几乎平均增长,在两条海沟之间形成扩张中心。这些模型结果可以重建新泰西山脉东部地区的新生代演化,最终导致安达曼俯冲带的发展。我们还展示了白垩纪后印度-欧亚大陆碰撞带的演化,这是多大陆块存在下的 SDDS 动力的结果。这些动力促进了板块断裂,在相对较短的时间内(3 Myr)将SDDS转变为单一的俯冲系统。最后,我们从这些SDDS模型的角度对新特提斯古构造进行了综合分析。
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来源期刊
Earth and Planetary Science Letters
Earth and Planetary Science Letters 地学-地球化学与地球物理
CiteScore
10.30
自引率
5.70%
发文量
475
审稿时长
2.8 months
期刊介绍: Earth and Planetary Science Letters (EPSL) is a leading journal for researchers across the entire Earth and planetary sciences community. It publishes concise, exciting, high-impact articles ("Letters") of broad interest. Its focus is on physical and chemical processes, the evolution and general properties of the Earth and planets - from their deep interiors to their atmospheres. EPSL also includes a Frontiers section, featuring invited high-profile synthesis articles by leading experts on timely topics to bring cutting-edge research to the wider community.
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