利用 MAARSY 监测挪威北部极地对流层上部和平流层下部波浪的间歇性

IF 3.8 2区地球科学 Q2 METEOROLOGY & ATMOSPHERIC SCIENCES Journal of Geophysical Research: Atmospheres Pub Date : 2024-08-08 DOI:10.1029/2024JD040938

Priyanka Ghosh, Toralf Renkwitz, Laura Holt, Masaki Tsutsumi, Ralph Latteck, Jorge L. Chau

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引用次数: 0

摘要

我们利用挪威安多亚（69.30°N，16.04°E）的中层大气阿洛玛雷达系统研究了2017-2022年对流层上部和平流层下部（UTLS）重力波的绝对动量通量（AMF）和垂直风方差以及间歇现象。我们将 AMF 和分为不同的周期范围（30 分钟-2 小时、2-6 小时、6-13 小时、13 小时-1 天和 30 分钟-1 天），以研究短周期和长周期波的意义。这些周期带的选择是基于现有频谱的边界条件：30 分钟（奈奎斯特频率）、13 小时（惯性周期）和 1 天（基于我们对最大长周期振荡的兴趣）。我们希望通过对 AMF 和 , 的研究，详细确定北极纬度的全球大气环流特征。此外，对间歇性的评估也至关重要，因为它在很大程度上影响并改变着全球大气环流的属性。我们的新结果表明 AMF 和：(a) 季节性变化，夏季（5 月至 9 月）为最小值；(b) 对流层上部（<9.00公里）比平流层下部的幅度大；（c）短周期成分（30分钟-2小时，2-6小时）在整个UTLS中的间歇性更强；以及（d）长周期成分（6-13小时，13小时-1天）在夏季对流层上部（平流层下部）的间歇性较低（较高），这意味着存在一种合理的滤波机制。

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Intermittency of Waves in the Polar Upper Troposphere and Lower Stratosphere Over Northern Norway Using MAARSY

We investigate the absolute momentum flux (AMF) and vertical wind variance $(ρ \overline{w^{' 2}})$ of gravity waves (GWs) along with intermittencies in the upper troposphere and lower stratosphere (UTLS) during 2017–2022 using the Middle Atmosphere Alomar Radar System at Andøya, Norway (69.30°N, 16.04°E). We categorized the AMF and $ρ \overline{w^{' 2}}$ into different period ranges (30 min–2 hr, 2–6 hr, 6–13 hr, 13 hr–1 day, and 30 min–1 day) to study the significance of short- and long-period waves. The selection of these period bands was based on the boundary conditions of the available spectra: 30 min (Nyquist frequency), 13 hr (inertial period), and 1 day (based on our interest in maximum long-period oscillations). Through the investigation of the AMF and $ρ \overline{w^{' 2}}$ , we wish to determine in detail the GW characteristics at northern polar latitudes. Furthermore, it is crucial to assess the intermittency as it considerably influences and alters the GW attributes. Our novel results indicate for both AMF and $ρ \overline{w^{' 2}}$ : (a) seasonal variation with minima during summer (May–September); (b) higher magnitude in the upper troposphere (<9.00 km) than the lower stratosphere; (c) short-period components (30 min–2 hr, 2–6 hr) are more intermittent in the entire UTLS; and (d) the long-period components (6–13 hr, 13 hr–1 day) demonstrate lower (higher) intermittency in the upper troposphere (lower stratosphere) in summer implying a plausible wave-filtering mechanism.

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来源期刊

Journal of Geophysical Research: Atmospheres Earth and Planetary Sciences-Geophysics

CiteScore

7.30

自引率

11.40%

发文量

684

期刊介绍： JGR: Atmospheres publishes articles that advance and improve understanding of atmospheric properties and processes, including the interaction of the atmosphere with other components of the Earth system.