Large-scale circulation reversals explained by pendulum correspondence

IF 3.6 2区工程技术 Q1 MECHANICS Journal of Fluid Mechanics Pub Date : 2024-09-13 DOI:10.1017/jfm.2024.584

Nicholas J. Moore, Jinzi Mac Huang

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Abstract

We introduce a low-order dynamical system to describe thermal convection in an annular domain. The model derives systematically from a Fourier–Laurent truncation of the governing Navier–Stokes Boussinesq equations and accounts for spatial dependence of the flow and temperature fields. Comparison with fully resolved direct numerical simulations (DNS) shows that the model captures parameter bifurcations and reversals of the large-scale circulation (LSC), including states of (i) steady circulating flow, (ii) chaotic LSC reversals and (iii) periodic LSC reversals. Casting the system in terms of the fluid's angular momentum and centre of mass (CoM) reveals equivalence to a damped pendulum with forcing that raises the CoM above the fulcrum. This formulation offers a transparent mechanism for LSC reversals, namely the inertial overshoot of a forced pendulum, and it yields an explicit formula for the frequency

$f^*$

of regular LSC reversals in the high-Rayleigh-number (Ra) limit. This formula is shown to be in excellent agreement with DNS and produces the scaling law

$f^* \sim {Ra}^{0.5}$

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用钟摆对应关系解释大尺度环流逆转

我们引入了一个低阶动力学系统来描述环形域中的热对流。该模型系统地源自纳维-斯托克斯-布西内斯克方程的傅立叶-洛朗截断，并考虑了流动和温度场的空间依赖性。与完全解析直接数值模拟（DNS）的比较表明，该模型捕捉到了大尺度环流（LSC）的参数分岔和逆转，包括（i）稳定环流、（ii）混乱 LSC 逆转和（iii）周期性 LSC 逆转等状态。从流体角动量和质心（CoM）的角度来看，该系统等同于一个阻尼摆，迫使质心上升到支点之上。这种表述为 LSC 反转提供了一个透明的机制，即受迫摆的惯性过冲，并产生了高雷利数（Ra）极限下规则 LSC 反转频率 $f^*$ 的明确公式。结果表明，该公式与 DNS 非常吻合，并产生了缩放定律 $f^* \sim {Ra}^{0.5}$ 。

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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来源期刊

Journal of Fluid Mechanics 物理-力学

CiteScore

6.50

自引率

27.00%

发文量

945

审稿时长

5.1 months

期刊介绍： Journal of Fluid Mechanics is the leading international journal in the field and is essential reading for all those concerned with developments in fluid mechanics. It publishes authoritative articles covering theoretical, computational and experimental investigations of all aspects of the mechanics of fluids. Each issue contains papers on both the fundamental aspects of fluid mechanics, and their applications to other fields such as aeronautics, astrophysics, biology, chemical and mechanical engineering, hydraulics, meteorology, oceanography, geology, acoustics and combustion.

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