Earth’s tectonic and plate boundary evolution over 1.8 billion years

IF 8.5 1区 地球科学 Q1 GEOSCIENCES, MULTIDISCIPLINARY Geoscience frontiers Pub Date : 2024-08-31 DOI:10.1016/j.gsf.2024.101922
Xianzhi Cao , Alan S. Collins , Sergei Pisarevsky , Nicolas Flament , Sanzhong Li , Derrick Hasterok , R. Dietmar Müller
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Abstract

Understanding the intricate relationships between the solid Earth and its surface systems in deep time necessitates comprehensive full-plate tectonic reconstructions that include evolving plate boundaries and oceanic plates. In particular, a tectonic reconstruction that spans multiple supercontinent cycles is important to understand the long-term evolution of Earth’s interior, surface environments and mineral resources. Here, we present a new full-plate tectonic reconstruction from 1.8 Ga to present that combines and refines three published models: one full-plate tectonic model spanning 1 Ga to present and two continental-drift models focused on the late Paleoproterozoic to Mesoproterozoic eras. Our model is constrained by geological and geophysical data, and presented as a relative plate motion model in a paleomagnetic reference frame. The model encompasses three supercontinents, Nuna (Columbia), Rodinia, and Gondwana/Pangea, and more than two complete supercontinent cycles, covering ∼40% of the Earth’s history. Our refinements to the base models are focused on times before 1.0 Ga, with minor changes for the Neoproterozoic. For times between 1.8 Ga and 1.0 Ga, the root mean square speeds for all plates generally range between 4 cm/yr and 7 cm/yr (despite short-term fast motion around 1.1 Ga), which are kinematically consistent with post-Pangean plate tectonic constraints. The time span of the existence of Nuna is updated to between 1.6 Ga (1.65 Ga in the base model) and 1.46 Ga based on geological and paleomagnetic data. We follow the base models to leave Amazonia/West Africa separate from Nuna (as well as Western Australia, which only collides with the remnants of Nuna after initial break-up), and South China/India separate from Rodinia. Contrary to the concept of a “boring billion”, our model reveals a dynamic geological history between 1.8 Ga and 0.8 Ga, characterized by supercontinent assembly and breakup, and continuous accretion events. The model is publicly accessible, providing a framework for future refinements and facilitating deep time studies of Earth’s system. We suggest that the model can serve as a valuable working hypothesis, laying the groundwork for future hypothesis testing.

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18 亿年来地球构造和板块边界的演变
要了解固体地球及其表面系统在深部时间的复杂关系,就必须进行全面的全板块构造重建,其中包括不断演变的板块边界和大洋板块。特别是,跨越多个超大陆周期的构造重建对于了解地球内部、地表环境和矿产资源的长期演化非常重要。在这里,我们提出了一个从 1.8 Ga 到现在的新的全板块构造重建,它结合并完善了三个已发表的模型:一个跨越 1 Ga 到现在的全板块构造模型和两个侧重于晚古生代到中古生代的大陆漂移模型。我们的模型受到地质和地球物理数据的制约,是在古地磁参考框架下的相对板块运动模型。该模型包括三个超大陆,即努纳大陆(哥伦比亚)、罗迪尼亚大陆和冈瓦纳/泛大陆,以及两个以上完整的超大陆周期,涵盖了地球历史的 40%。我们对基本模型的改进主要集中在 1.0 Ga 之前,对新近纪略有改动。在 1.8 Ga 到 1.0 Ga 之间,所有板块的均方根速度一般在 4 cm/yr 到 7 cm/yr 之间(尽管在 1.1 Ga 附近有短期的快速运动),这在运动学上与后泛大陆板块构造的约束相一致。根据地质和古地磁数据,努纳存在的时间跨度更新为 1.6 Ga(基础模型为 1.65 Ga)和 1.46 Ga 之间。我们沿用了基础模型,将亚马孙/西非从努纳星分离出来(以及西澳大利亚,它只是在最初解体后才与努纳星的残余部分相撞),并将华南/印度从罗迪尼亚分离出来。与 "无聊的十亿 "概念相反,我们的模型揭示了 1.8 Ga 到 0.8 Ga 之间的动态地质历史,其特点是超大陆的组装和解体,以及持续的增生事件。该模型可公开访问,为未来的改进提供了一个框架,并促进了对地球系统的深时研究。我们认为该模型可以作为一个有价值的工作假设,为未来的假设检验奠定基础。
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来源期刊
Geoscience frontiers
Geoscience frontiers Earth and Planetary Sciences-General Earth and Planetary Sciences
CiteScore
17.80
自引率
3.40%
发文量
147
审稿时长
35 days
期刊介绍: Geoscience Frontiers (GSF) is the Journal of China University of Geosciences (Beijing) and Peking University. It publishes peer-reviewed research articles and reviews in interdisciplinary fields of Earth and Planetary Sciences. GSF covers various research areas including petrology and geochemistry, lithospheric architecture and mantle dynamics, global tectonics, economic geology and fuel exploration, geophysics, stratigraphy and paleontology, environmental and engineering geology, astrogeology, and the nexus of resources-energy-emissions-climate under Sustainable Development Goals. The journal aims to bridge innovative, provocative, and challenging concepts and models in these fields, providing insights on correlations and evolution.
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