Low inertia reversing geodynamos

arXiv - PHYS - Geophysics Pub Date : 2024-08-14 DOI:arxiv-2408.07420

Chris Jones, Yue-Kin Tsang

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Abstract

Convection driven geodynamo models in rotating spherical geometry have regimes in which reversals occur. However, reversing dynamo models are usually found in regimes where the kinetic and magnetic energy is comparable, so that inertia is playing a significant role in the dynamics. In the Earth's core, the Rossby number is very small, and the magnetic energy is much larger than the kinetic energy. Here we investigate dynamo models in the strong field regime, where magnetic forces have a significant effect on convection. In the core, the strong field is achieved by having the magnetic Prandtl number Pm small, but the Ekman number E extremely small. In simulations, very small E is not possible, but the strong field regime can be reached by increasing Pm. However, if Pm is raised while the fluid Prandtl number is fixed at unity, the most common choice, the Peclet number number becomes small, so that the linear terms in the heat (or composition) equation dominate, which is also far from Earth-like behaviour. Here we increase Pr and Pm together, so that nonlinearity is important in the heat equation and the dynamo is strong field. We find that Earth-like reversals are possible at numerically achievable parameter values, and the simulations have Earth-like magnetic fields away from the times at which it reverses. The magnetic energy is much greater than the kinetic energy except close to reversal times.

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低惯性反向地球动力装置

旋转球形几何中的对流驱动地球动力模型有发生逆转的情况。然而，逆转动力模型通常出现在动能和磁能相当的情况下，因此惯性在动力学中起着重要作用。在地核中，罗斯比数非常小，磁能远大于动能。在这里，我们研究了强磁场机制下的动力模型，在强磁场机制下，磁力对对流有重要影响。在地核中，强磁场是通过使磁性普朗特数 Pm 较小，但埃克曼数 E 极小来实现的。在模拟中，不可能实现极小的 E，但可以通过增大 Pm 达到强磁场状态。然而，如果提高 Pm，同时将流体普朗特数固定为一，即最常见的选择，则佩克莱特数会变小，从而使热量（或成分）方程中的线性项占主导地位，这也与类地球行为相去甚远。在这里，我们同时增加了 Pr 和 Pm，从而使非线性在热方程中变得重要，而动力则成为强场。我们发现，在数值可实现的参数值下，类似地球的逆转是可能的，而且模拟结果在逆转时间之外也有类似地球的磁场。磁能远大于动能，除非接近逆转时间。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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arXiv - PHYS - Geophysics

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