Rapid geomagnetic variations and stable stratification at the top of Earth's core

IF 1.9 3区地球科学 Q2 GEOCHEMISTRY & GEOPHYSICS

Physics of the Earth and Planetary Interiors Pub Date : 2025-03-11 DOI:10.1016/j.pepi.2025.107335

Julien Aubert

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Abstract

Probing the possible presence and physical properties of a stably stratified layer atop Earth's core is crucial to better determine the past history and heat budget of the planet. This has previously been done by ascribing a variety of interannual to decadal geomagnetic variations to hydromagnetic waves internal to the layer. This study presents the first self-consistent simulation of the stratified layer dynamics in interplay with the underlying core convection, in physical conditions matching those of Earth's core. Magneto-Archimedes-Coriolis waves of decadal periods appear in stratified layers deeper than a few tens of kilometers and with Brunt-Väisälä frequency matching the rotation rate of the planet. However, the level at which core convection excites these waves is generally insufficient to account for observed geomagnetic variations in this period range. Strong stratification is furthermore deleterious to a number of observed features that unstratified models are successful at reproducing. Fluid flow at the core surface decouples from the interior and becomes strongly dissimilar to geomagnetic inferences. Magnetic jerks and their corresponding near-equatorial, rapidly alternating magnetic acceleration patterns also disappear, because the supporting interannual magneto-Coriolis waves are impeded by the stratified layer. This negative impact on the reproduction of the observed rapid geomagnetic variations limits the possible extent of a stable top layer to the first few tens of kilometers beneath Earth's core surface.

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快速的地磁变化和地核顶部的稳定分层

探测地核上可能存在的稳定分层层及其物理性质，对于更好地确定地球过去的历史和热量收支至关重要。以前的方法是把各种年际或年代际地磁变化归因于地层内部的水磁波。本研究首次提出了在与地核物理条件相匹配的条件下，与底层核心对流相互作用的分层层动力学的自洽模拟。年代代期的磁-阿基米德-科里奥利波出现在深度超过几十公里的分层层中，其Brunt-Väisälä频率与行星的自转速度相匹配。然而，核心对流激发这些波的水平通常不足以解释在这一时期范围内观测到的地磁变化。此外，强分层对一些观察到的特征是有害的，而这些特征是非分层模型能够成功再现的。岩心表面的流体流动与内部分离，并且变得与地磁推断强烈不同。由于支持的年际磁科里奥利波受到层状层的阻碍，磁跳变及其相应的近赤道、快速交替磁加速模式也消失了。这种对观测到的快速地磁变化的再现的负面影响，将稳定的顶层的可能范围限制在地核表面以下的最初几十公里。

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来源期刊

Physics of the Earth and Planetary Interiors 地学天文-地球化学与地球物理

CiteScore

5.00

自引率

4.30%

发文量

审稿时长

18.5 weeks

期刊介绍： Launched in 1968 to fill the need for an international journal in the field of planetary physics, geodesy and geophysics, Physics of the Earth and Planetary Interiors has now grown to become important reading matter for all geophysicists. It is the only journal to be entirely devoted to the physical and chemical processes of planetary interiors. Original research papers, review articles, short communications and book reviews are all published on a regular basis; and from time to time special issues of the journal are devoted to the publication of the proceedings of symposia and congresses which the editors feel will be of particular interest to the reader.