大陆分裂过程中的超慢横波

Antonio Schettino , Giorgio Ranalli
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引用次数: 0

摘要

大陆裂谷作用是威尔逊旋回的四个基本地质过程之一。裂谷作用是大陆岩石圈持续拉伸的结果,涉及力学、热力学和流变过程。随后可能是灾难性的破裂阶段,它决定了伸展变形的停止,并最终将一个大陆分离为两个不同的构造板块,这两个板块是通过海洋岩石圈的吸积而生长的。到目前为止,人们还没有完全了解向海底扩张的过渡以及开发新海洋的条件。我们建议,对这一过程的一致描述必须考虑地幔岩石圈中长期滞后弹性的存在、该层的超绝热条件,以及这种弹性力与热异常引起的局部浮力的联合作用。我们提出了岩石圈-地幔非线性粘弹性模型的流变方程的解,数值实验表明,在伸展过程中产生了瞬态热异常,导致形成波长数百至数千公里、周期数十公里的横波。这些波浪引起地形振荡并影响地形起伏。因此,它们可能是轴向裂谷湖泊系统和位于反向排水区域的离轴(树枝状)湖泊中的海平面旋回的原因。在足够高的伸展速率下,变形局部化,这些超慢波决定了循环剪切破坏,通过岩石圈形成X形交叉结构,这是最终破裂的前奏。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Ultra-slow transverse waves during continental breakup

Continental rifting is one of the four fundamental geological processes of the Wilson cycle. Rifting results from the continuous stretching of continental lithosphere and involves mechanical, thermodynamic, and rheological processes. It may be followed by a catastrophic breakup stage, which determines cessation of extensional deformation and the final separation of a continent into two distinct tectonic plates that grow by accretion of oceanic lithosphere. To date, the transition to sea−floor spreading and the conditions for the development of a new ocean have not been fully understood. We propose that a consistent description of this process must consider the existence of long−term retarded elasticity in the mantle lithosphere, the superadiabatic conditions of this layer, and the combined action of such elastic forces with the localized buoyancy arising from thermal anomalies. We present a solution of the rheological equation for a nonlinear viscoelastic model of the lithosphere mantle and numerical experiments showing that transient thermal anomalies are generated during the extension, which lead to the formation of transverse waves having wavelengths of the order of hundreds to thousands km and periods of several tens kyrs. These waves induce oscillating topography and influence the relief. Therefore, they could be responsible for eustatic cycles both in the axial rift lacustrine system and in off−axis (dendritic) lakes placed in areas of reversed drainage. At sufficiently high extension rates, deformation localizes and these ultra-slow waves determine cyclic shear failure, with formation of X−shaped cross structures through the lithosphere that prelude to the final rupture.

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