Various approximations of mathematical models of planetary internal gravity waves in the f-plane approximation

IF 2 4区地球科学 Q2 GEOCHEMISTRY & GEOPHYSICS

Dynamics of Atmospheres and Oceans Pub Date : 2025-10-15 DOI:10.1016/j.dynatmoce.2025.101604

Robert G. Zakinyan, Andrey V. Chernyshov, Arthur R. Zakinyan

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Abstract

The paper proposes a mathematical model describing the propagation of internal inertial-gravity waves (IIGWs) in a stratified atmosphere. The necessity to propose a novel mathematical model stems from the fact that, as shown in the paper, the temperature disturbance field in the existing mathematical models depicting internal gravity waves (IGWs) in the incompressible fluid and anelastic gas approximations is not consistent with the temperature disturbance field derived from the heat conduction equation. In these models, the temperature field is obtained from the diagnostic Boussinesq relation, which states a direct proportionality between the density disturbance (or potential temperature disturbance) and the temperature disturbance. The temperature field in the compressible fluid approximation is consistent, yet it also describes the acoustic spectrum. In this paper, we propose a mathematical model describing the IIGWs in the compressible fluid approximation. In this model, the temperature field is consistent with the heat conduction equation, and the acoustic spectrum is absent. The paper also proposes a general mathematical model for the propagation of IIGWs in a baroclinic atmosphere. This model differs from the compressible fluid approximation in that the state of an air parcel is described not by the adiabatic equation, but by the Mendeleev–Clapeyron equation.

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f平面近似中行星内部重力波数学模型的各种近似

本文提出了一个描述内部惯性重力波（IIGWs）在分层大气中传播的数学模型。提出一种新的数学模型的必要性在于，如本文所示，现有的描述不可压缩流体和非弹性气体近似中的内重力波的数学模型中的温度扰动场与由热传导方程导出的温度扰动场不一致。在这些模型中，温度场由诊断Boussinesq关系获得，该关系表明密度扰动（或势温扰动）与温度扰动成正比关系。可压缩流体近似中的温度场是一致的，但它也描述了声谱。在本文中，我们提出了一个在可压缩流体近似中描述iigw的数学模型。在该模型中，温度场与热传导方程一致，声谱缺失。本文还提出了斜压大气中iigw传播的一般数学模型。这个模型与可压缩流体近似的不同之处在于，空气包的状态不是由绝热方程描述的，而是由门捷列夫-克拉珀龙方程描述的。

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

Dynamics of Atmospheres and Oceans 地学-地球化学与地球物理

CiteScore

3.10

自引率

5.90%

发文量

审稿时长

>12 weeks

期刊介绍： Dynamics of Atmospheres and Oceans is an international journal for research related to the dynamical and physical processes governing atmospheres, oceans and climate. Authors are invited to submit articles, short contributions or scholarly reviews in the following areas: •Dynamic meteorology •Physical oceanography •Geophysical fluid dynamics •Climate variability and climate change •Atmosphere-ocean-biosphere-cryosphere interactions •Prediction and predictability •Scale interactions Papers of theoretical, computational, experimental and observational investigations are invited, particularly those that explore the fundamental nature - or bring together the interdisciplinary and multidisciplinary aspects - of dynamical and physical processes at all scales. Papers that explore air-sea interactions and the coupling between atmospheres, oceans, and other components of the climate system are particularly welcome.