Self-Induced Gravity Wave Attenuation and Breaking With Generation of Secondary Modes in the Lower Mesosphere During Two SOUTHTRAC Flights Above the Andes

IF 3.8 2区地球科学 Q2 METEOROLOGY & ATMOSPHERIC SCIENCES

Journal of Geophysical Research: Atmospheres Pub Date : 2025-04-24 DOI:10.1029/2024JD042981

P. Alexander, A. de la Torre, T. Marcos, R. Hierro, N. Kaifler, S. Rhode, M. Geldenhuys

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引用次数: 0

Abstract

We combine lidar temperature observations onboard a research aircraft with numerical simulations in the framework of the SOUTHTRAC (Southern Hemisphere Transport, Dynamics, and Chemistry) Campaign. Deep propagation of gravity waves (GW) from the troposphere to the lower mesosphere is studied above the Southern Andes during two flights in September 2019. We use the Weather Research and Forecasting (WRF) model with a configuration for the simulations that has been validated in a previous study of this campaign. Strong orographic GW were detected during both flights that were conceived for different latitudes. The observational and numerical data reveal the presence of significant GW attenuation, breaking and secondary wave generation above the stratopause due to the development of convective and dynamic instability as well as conditions for wave evanescence. The GW generated by topography were not able to alter the stable structure of the stratosphere, but the scenario was quite different in the lower mesosphere. The disturbed zones in that layer were produced by the combined effect on lapse rate of the background temperature variation and the perturbations associated with GW, which together may induce large vertical gradients. As a consequence, areas of reduced stability (with low or even negative buoyancy parameter) emerge above the stratopause. The existence of these GW self-induced attenuation layers in the mesosphere where temperature perturbations produce large negative gradients may lead to an amplitude growth control mechanism for the upward propagating waves.

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在安第斯山脉上空进行的两次 SOUTHTRAC 飞行期间，低层中间层的自诱发重力波衰减和断裂与次级模式的产生

我们在南半球传输、动力学和化学运动（SOUTHTRAC）框架内，将研究飞机上的激光雷达温度观测与数值模拟相结合。在2019年9月的两次飞行中，我们在南安第斯山脉上空研究了重力波（GW）从对流层向低层中间层的深层传播。我们使用天气研究与预报（WRF）模型进行模拟，该模型的配置已在之前的研究中得到验证。在两次飞行中都探测到了不同纬度的强烈气旋全球风暴。观测和数值数据显示，由于对流和动态不稳定性的发展，以及波浪衰减的条件，在平流层顶以上存在明显的全球大气环流衰减、断裂和次级波浪生成。地形产生的全球大气环流无法改变平流层的稳定结构，但在低层中间层的情况却大不相同。该层的扰动区是由背景温度变化和与全球大气环流相关的扰动对失效率的综合影响造成的，这两种因素可能共同导致较大的垂直梯度。因此，平流层顶以上出现了稳定性降低的区域（浮力参数较低甚至为负）。在温度扰动产生较大负梯度的中间层，存在这些全球大气环流自致衰减层，可能会导致向上传播的波的振幅增长控制机制。

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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.