Decomposition of vertical velocity and its zonal wavenumber kinetic energy spectra in the hydrostatic atmosphere

IF 3 3区地球科学 Q2 METEOROLOGY & ATMOSPHERIC SCIENCES

Journal of the Atmospheric Sciences Pub Date : 2023-09-25 DOI:10.1175/jas-d-23-0090.1

Nedjeljka Žagar, Valentino Neduhal, Sergiy Vasylkevych, Žiga Zaplotnik, Hiroshi L. Tanaka

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Abstract

Abstract The spectrum of kinetic energy of vertical motions (VKE) is less well understood compared to the kinetic energy spectrum of horizontal motions (HKE). One challenge that has limited progress in describing the VKE spectrum is a lack of a unified approach to the decomposition of vertical velocities associated with the Rossby motions and inertia-gravity (IG) wave flows. This paper presents such a unified approach using a linear Rossby-IG vertical velocity normal-mode decomposition appropriate for a spherical, hydrostatic atmosphere. New theoretical developments show that for every zonal wavenumber k , the limit VKE is proportional to the total mechanical energy and to the square of the frequency of the normal mode. The theory predicts a VKE ∝ k −5 and a VKE ∝ k 1/3 power law for the Rossby and IG waves, assuming a k −3 and a k −5/3 power law for the Rossby and IG HKE spectra, respectively. The Kelvin and mixed Rossby-gravity wave VKE spectra are predicted to follow k −1 and k −5 power laws, respectively. The VKE spectra for ERA5 analyses from August 2018 show that the Rossby VKE spectra approximately follow the predicted a k −5 power law. The expected k 1/3 power law for the gravity wave VKE spectrum is found only in the SH midlatitude stratosphere for k ≈ 10−60. The inertial range IG VKE spectra in the tropical and midlatitude troposphere reflect a mixture of ageostrophic and convection-coupled dynamics and have slopes between −1 and −1/3, likely associated with too steep IG HKE spectra. The forcing by quasi-geostrophic ageostrophic motions is seen as an IG VKE peak at synoptic scales in the SH upper troposphere which gradually moves to planetary scales in the stratosphere.

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静水大气中垂直速度分解及其纬向波数动能谱

摘要与水平运动的动能谱相比，人们对垂直运动的动能谱了解较少。在描述VKE频谱方面，一个限制进展的挑战是缺乏统一的方法来分解与罗斯比运动和惯性重力(IG)波流相关的垂直速度。本文提出了这样一种统一的方法，使用适用于球形流体静力大气的线性rosssby - ig垂直速度正态分解。新的理论发展表明，对于每一个纬向波数k，极限VKE与总机械能和正态模态频率的平方成正比。该理论预测罗斯比波和IG波的VKE∝k−5和VKE∝k 1/3幂律，假设罗斯比和IG HKE谱分别为k−3和k−5/3幂律。预计开尔文和混合罗斯-重力波VKE谱分别遵循k−1和k−5幂定律。2018年8月ERA5分析的VKE谱表明，rosby VKE谱大致遵循预测的k−5幂定律。重力波VKE谱的k 1/3幂律只存在于SH中纬度平流层，k≈10−60。热带和中纬度对流层的惯性范围IG VKE谱反映了地转和对流耦合动力学的混合，斜率在- 1和- 1/3之间，可能与过于陡峭的IG HKE谱有关。准地转地转运动的强迫在对流层上层的天气尺度上被看作是一个IG VKE峰值，在平流层逐渐移动到行星尺度。

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来源期刊

Journal of the Atmospheric Sciences 地学-气象与大气科学

CiteScore

0.20

自引率

22.60%

发文量

196

审稿时长

3-6 weeks

期刊介绍： The Journal of the Atmospheric Sciences (JAS) publishes basic research related to the physics, dynamics, and chemistry of the atmosphere of Earth and other planets, with emphasis on the quantitative and deductive aspects of the subject. The links provide detailed information for readers, authors, reviewers, and those who wish to submit a manuscript for consideration.