经历弱进动的旋转球体中的局部热对流

IF 1.1 4区地球科学 Q3 ASTRONOMY & ASTROPHYSICS

Geophysical and Astrophysical Fluid Dynamics Pub Date : 2020-07-27 DOI:10.1080/03091929.2020.1791844

K. Lam, D. Kong, Keke Zhang

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引用次数: 2

摘要

我们报告了在经典的热对流问题中发现的一个新的非线性现象，这个热对流问题发生在一个快速旋转的、自重力的、内部加热的流体球中，它也经历了弱进动。当普朗特数足够大时，对流驱动的柱状涡旋——几乎是地转的，方位角尺度小——不能与进动驱动的流发生实质性的非线性相互作用，进动驱动的流在地幔参参考系中以赤道反对称的大尺度惯性波的形式存在。当普朗特数足够小时，对流驱动的流动，由于其动力学中主要的惯性效应，是非地转的，并以等对称的大尺度惯性波的形式存在，因此，能够通过非线性效应与进动驱动的大尺度惯性波破坏性地相互作用。我们揭示了对流驱动波和进动驱动波之间的破坏性相互作用导致局域对流波，它几乎是等对称的，在方位角方向上逐渐传播，并且很大程度上被限制在球体的四分之一内。

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Localised thermal convection in rotating spheres that undergo weak precession

We report a new nonlinear phenomenon discovered in the classical problem of thermal convection in a rapidly rotating, self-gravitating, internally heated fluid sphere that also undergoes weak precession. When the Prandtl number of fluids is sufficiently large, convection-driven columnar rolls – which are nearly geostrophic and marked by small azimuthal scale – cannot have substantial nonlinear interaction with precession-driven flow that is in the form of an equatorially antisymmetric, large-scale inertial wave in the mantle frame of reference. When the Prandtl number of fluids is sufficiently small, convection-driven flow, because of predominant inertial effects in its dynamics, is non-geostrophic and in the form of an equatorially symmetric, large-scale inertial wave, and, hence, is able to interact destructively with the precession-driven large-scale inertial wave via nonlinear effects. We reveal that the destructive interaction between the convection-driven wave and the precession-driven wave leads to a localised convective wave that is nearly equatorially symmetric, progradely travelling in the azimuthal direction, and largely confined within a quarter of the sphere.

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来源期刊

Geophysical and Astrophysical Fluid Dynamics 地学天文-地球化学与地球物理

CiteScore

3.10

自引率

0.00%

发文量

审稿时长

>12 weeks

期刊介绍： Geophysical and Astrophysical Fluid Dynamics exists for the publication of original research papers and short communications, occasional survey articles and conference reports on the fluid mechanics of the earth and planets, including oceans, atmospheres and interiors, and the fluid mechanics of the sun, stars and other astrophysical objects. In addition, their magnetohydrodynamic behaviours are investigated. Experimental, theoretical and numerical studies of rotating, stratified and convecting fluids of general interest to geophysicists and astrophysicists appear. Properly interpreted observational results are also published.