具有相位变化的降水拟地转方程的收敛性:渐近性和数值评价

Yeyu Zhang, L. Smith, S. Stechmann
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引用次数: 5

摘要

准地转方程在我们理解大气和海洋流体动力学方面起着至关重要的作用。然而,传统的QG方程描述的是“干”动力学,没有考虑到水分和云。为了超越干燥设置,沉淀QG (PQG)方程最近已使用形式渐近推导。本文研究了具有相变的湿Boussinesq方程是否收敛于PQG方程。先验地,相位界面(云边缘)的非线性可能会使收敛复杂化。本文给出了收敛性和非收敛性的数值研究。数值模拟考虑了ε =0.1、0.01和0.001的情况,其中ε与罗斯比数和弗劳德数成正比。在数值模拟中,垂直速度w(或其他衡量不平衡和惯性重力波的指标)的大小随着柱的减小而近似成正比,这表明趋同于PQG动力学。这些措施在固定时间T为O(1)时进行量化,并且数值数据也表明在以后的时间收敛的可能性。本文是主题问题“物理流体动力学中的数学问题(第二部分)”的一部分。
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Convergence to precipitating quasi-geostrophic equations with phase changes: asymptotics and numerical assessment
The quasi-geostrophic (QG) equations play a crucial role in our understanding of atmospheric and oceanic fluid dynamics. Nevertheless, the traditional QG equations describe ‘dry’ dynamics that do not account for moisture and clouds. To move beyond the dry setting, precipitating QG (PQG) equations have been derived recently using formal asymptotics. Here, we investigate whether the moist Boussinesq equations with phase changes will converge to the PQG equations. A priori, it is possible that the nonlinearity at the phase interface (cloud edge) may complicate convergence. A numerical investigation of convergence or non-convergence is presented here. The numerical simulations consider cases of ϵ=0.1, 0.01 and 0.001, where ϵ is proportional to the Rossby and Froude numbers. In the numerical simulations, the magnitude of vertical velocity w (or other measures of imbalance and inertio-gravity waves) is seen to be approximately proportional to ϵ as ϵ decreases, which suggests convergence to PQG dynamics. These measures are quantified at a fixed time T that is O(1), and the numerical data also suggests the possibility of convergence at later times. This article is part of the theme issue ‘Mathematical problems in physical fluid dynamics (part 2)’.
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