Tropopause folds over the Tibetan Plateau and their impact on water vapor in the upper troposphere-lower stratosphere

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

Climate Dynamics Pub Date : 2023-10-14 DOI:10.1007/s00382-023-06978-2

Yongpeng Zhang, Qian Huang, Kun Guo, Mengyuan Wang, Huiren Liao, Yan Chou, Xin He

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Abstract

Abstract As one of the most important greenhouse gases, water vapor in the upper troposphere and lower stratosphere (UTLS) has a significant impact on the global earth-atmosphere system. The Tibetan Plateau (TP) is an important high terrain which exerts a profound impact on the change of weather and climate, and mass exchange. Tropopause folds occur frequently over the TP due to the impact of the subtropical westerly jet, which affects water vapor transport between the stratosphere and the troposphere. In this paper, the spatial and temporal distribution characteristics of tropopause folds over the TP are examined by applying an improved three-dimensional (3D) labeling algorithm to the ERA5 reanalysis data (1979 to 2019). The effects of different fold depths in various regions over the TP on the variations of UTLS water vapor are further studied. The results of a case study (25 February 2008) suggest that there is a good continuity in identification of the fold depth for the same fold event using the improved 3D labeling algorithm. The fold depth and height are consistent with the results of radiosonde data and ERA5 reanalysis data. The fold frequency over the TP shows an increasing trend in the last 41 years, with slightly lower frequency of medium folds than that of shallow folds, and lowest frequency of deep folds. There is increasing water vapor in the UTLS over the TP due to tropopause folds. The results indicate that tropopause folds enhance the horizontal divergence of water vapor in the UTLS and increase the vertical water vapor flux in the UTLS region. The folding over the plateau leads to increased moisture in the UTLS. It is argued that vertical velocity anomalies in the vicinity of the fold and subgrid perturbations have a significant impact on the increase of UTLS water vapor over the TP. The results of this work provide a scientific basis for a better understanding of the stratosphere-troposphere exchanges due to tropopause folds over the TP.

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青藏高原对流层顶褶皱及其对对流层上层-平流层下层水汽的影响

作为最重要的温室气体之一，对流层上层和平流层下层的水汽对全球地球-大气系统有着重要的影响。青藏高原是一个重要的高原地形，对天气气候变化和物质交换有着深远的影响。由于副热带西风急流的影响，青藏高原上空对流层顶褶皱频繁发生，影响了平流层和对流层之间的水汽输送。本文应用改进的三维标记算法对1979 ~ 2019年ERA5再分析数据进行了对流层顶褶皱的时空分布特征分析。进一步研究了TP不同区域不同褶皱深度对UTLS水汽变化的影响。一个案例研究(2008年2月25日)的结果表明，使用改进的三维标记算法在识别同一褶皱事件的褶皱深度方面具有良好的连续性。褶皱深度和高度与探空资料和ERA5再分析资料一致。近41 a来，青藏高原上的褶皱频次呈上升趋势，中褶皱频次略低于浅褶皱，深褶皱频次最低。由于对流层顶褶皱，赤道上空的水汽增多。结果表明，对流层顶褶皱增强了UTLS区域水汽的水平辐散，增加了UTLS区域的垂直水汽通量。高原上的褶皱导致UTLS的水分增加。认为褶皱附近的垂直速度异常和亚格网扰动对TP上空UTLS水汽的增加有显著影响。研究结果为更好地理解青藏高原对流层顶褶皱引起的平流层-对流层交换提供了科学依据。

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

Climate Dynamics 地学-气象与大气科学

CiteScore

8.80

自引率

15.20%

发文量

483

审稿时长

2-4 weeks

期刊介绍： The international journal Climate Dynamics provides for the publication of high-quality research on all aspects of the dynamics of the global climate system. Coverage includes original paleoclimatic, diagnostic, analytical and numerical modeling research on the structure and behavior of the atmosphere, oceans, cryosphere, biomass and land surface as interacting components of the dynamics of global climate. Contributions are focused on selected aspects of climate dynamics on particular scales of space or time. The journal also publishes reviews and papers emphasizing an integrated view of the physical and biogeochemical processes governing climate and climate change.