Early Earth “subduction”: short-lived, off-craton, shuffle tectonics, and no plate boundaries

IF 3.2 2区 地球科学 Q2 GEOSCIENCES, MULTIDISCIPLINARY Precambrian Research Pub Date : 2024-05-18 DOI:10.1016/j.precamres.2024.107431
O. Nebel , E.D. Vandenburg , F.A. Capitanio , R.H. Smithies , J. Mulder , P.A. Cawood
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Abstract

Subduction is a key geodynamic feature on modern Earth that drives crustal chemical diversity, bridging the atmo-, hydro-, and lithosphere, but remains an enigmatic, unique planetary feature. Indisputable is the critical role of subduction in shaping Earth’s geomorphology and crustal dichotomy (ocean vs continental crust) and its impacts on long-term climate, making it arguably the most important process on present-day Earth across all geosciences. It is thus important to understand to what degree, or if at all, subduction was operational during the billions of years that led to our geological status quo.

Here, we assess the feasibility of Archean subduction with a focus on early Earth geodynamics. We argue that convection-driven rifting, but not spreading, formed the first keels under the primordial crust, providing the necessary stability for crustal survival. These sections of crustal rejuvenation would counterintuitively forge the first stable proto-cratonic terranes, which later evolved into cratons. Hydrated upper crustal rocks were vital in generating early fluxed mantle melting and related volcanism, but also for partial melting in hydrated lower crustal sections within proto-cratons, giving rise to tonalite-trondhjemite granodiorites (TTGs). Both processes operated off- and on-craton, respectively, and required melting of hydrated crust and crustal convergence but are unrelated. Away from proto-cratonic regions of minor episodic divergence and rifting, relative motions were accommodated by convergence and shuffle tectonics, leading to Archean-style subduction in localised regions that were prone to destruction. This primitive form of subduction and crustal maturation has operated from the earliest Archean time in a plate-and-lid regime. Crucially, this ‘Archean subduction’ represents short-lived crustal shuffle-tectonics outside areas of today’s cratons with fluxed melting in upper mantle regions but does not resemble present-day Benioff-style subduction. The development of subduction akin to present-day processes towards the end of the Archean could plausibly have driven atmospheric oxygenation over a few hundred million years between ca. 2.8–2.3 Ga, with H-loss to space accompanied by atmospheric oxidation through subduction-related global volcanic SO2 emissions.

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地球早期的 "俯冲":持续时间短,偏离克拉通,洗牌构造,没有板块边界
俯冲是现代地球上的一个关键地球动力特征,它驱动地壳化学多样性,连接大气圈、水圈和岩石圈,但仍然是一个神秘而独特的行星特征。俯冲在塑造地球地貌和地壳二分法(海洋地壳与大陆地壳)方面的关键作用及其对长期气候的影响是无可争议的,因此它可以说是当今地球上所有地球科学中最重要的过程。因此,重要的是要了解在导致我们地质现状的数十亿年中,俯冲在多大程度上可以运作,或者说是否可以运作。在这里,我们以早期地球地球动力学为重点,评估了阿基坦俯冲的可行性。我们认为,对流驱动的断裂(而非扩张)形成了原始地壳下的第一批龙骨,为地壳生存提供了必要的稳定性。这些地壳年轻化区段反直觉地形成了第一批稳定的原克拉通地块,这些地块后来演变成了陨石坑。水合上地壳岩石对早期通量地幔熔融和相关火山活动的产生至关重要,同时也对原克拉通内水合下地壳部分的熔融起着重要作用,从而产生了黑云母-透闪石花岗闪长岩(TTGs)。这两个过程分别在陨石坑外和陨石坑内进行,都需要水合地壳的熔化和地壳辐合,但两者并不相关。在远离原克拉通地区的小规模偶发性分异和断裂的地方,相对运动被辐合和洗牌构造所容纳,从而在容易遭到破坏的局部地区形成了阿基坦式的俯冲。这种原始形式的俯冲和地壳成熟从最早的阿基坦时期就开始在板块-盖层机制中运行。最重要的是,这种 "Archean俯冲 "代表了在今天的陨石坑区域之外的短暂地壳洗牌构造,在上地幔区域有通量熔融,但与今天的贝尼奥夫式俯冲并不相似。在大约 2.8-2.3 Ga 之间的几亿年中,与当今过程类似的俯冲在阿奇安末期的发展可能推动了大气的含氧量,H 损失到太空,同时通过与俯冲相关的全球火山 SO2 排放进行大气氧化。
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来源期刊
Precambrian Research
Precambrian Research 地学-地球科学综合
CiteScore
7.20
自引率
28.90%
发文量
325
审稿时长
12 months
期刊介绍: Precambrian Research publishes studies on all aspects of the early stages of the composition, structure and evolution of the Earth and its planetary neighbours. With a focus on process-oriented and comparative studies, it covers, but is not restricted to, subjects such as: (1) Chemical, biological, biochemical and cosmochemical evolution; the origin of life; the evolution of the oceans and atmosphere; the early fossil record; palaeobiology; (2) Geochronology and isotope and elemental geochemistry; (3) Precambrian mineral deposits; (4) Geophysical aspects of the early Earth and Precambrian terrains; (5) Nature, formation and evolution of the Precambrian lithosphere and mantle including magmatic, depositional, metamorphic and tectonic processes. In addition, the editors particularly welcome integrated process-oriented studies that involve a combination of the above fields and comparative studies that demonstrate the effect of Precambrian evolution on Phanerozoic earth system processes. Regional and localised studies of Precambrian phenomena are considered appropriate only when the detail and quality allow illustration of a wider process, or when significant gaps in basic knowledge of a particular area can be filled.
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