Stratospheric temperature features over Saudi Arabia and their relations with Atlantic SSTs and surface temperatures in winter

IF 1 4区地球科学 Q4 METEOROLOGY & ATMOSPHERIC SCIENCES

Atmosfera Pub Date : 2021-01-01 DOI:10.20937/atm.52937

H. Hasanean, A. Labban

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引用次数: 0

Abstract

Stratospheric weather and climate conditions are closely linked to tropospheric conditions. Stratospheric temperature is an important climatic factor regionally and globally. This paper studies temperature trends in the lower stratosphere at 50 hPa (T50), the mid-stratosphere at 30 hPa (T30) and the upper stratosphere at 10 hPa (T10) throughout winter and their impacts on Atlantic Ocean sea surface temperature and Saudi Arabian surface air temperature, SAT, in the period 1950-2019. The T50 trend over Saudi Arabia showed warming in 1959-1992 (first period) and cooling in 1993-2019 (second period). The T30 trend depicted progressive cooling throughout the overall period. The T10 trend revealed cooling overall with significant warming in the first period. Stratospheric temperatures influence climate change. The standard deviation outcomes showed relatively high inconsistencies in stratospheric-temperature time series. Analysis of the nonlinear trend in stratospheric temperature shows significant cooling for T30 and T10. A strong negative relationship exists between T10 and SST over the Atlantic Ocean. T50 indicates a strong negative relationship with the Atlantic multi-decadal oscillation (AMO) and the tropical southern Atlantic (TSA) indices. T30 relates more to the TSA and the northern tropical Atlantic (NTA) indices than T10 and T50. The lead-lag cross-correlation suggests that the SSTs of the Atlantic Ocean are linked to stratospheric temperatures at a zero lag for T10 and after three winter seasons for T50 and T30, with the exception of the TSA, which is linked at a zero lag. SSTs affect stratospheric temperatures as follows: 1) greenhouse gases from SSTs increase tropospheric temperatures while cooling the stratosphere, and 2) SSTs impact the vertical propagation of tropospheric waves entering the stratosphere. SAT/stratospheric temperature coupling occurs in winter, especially in the lower to mid-stratosphere layers.

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冬季沙特阿拉伯上空平流层温度特征及其与大西洋海温和地面温度的关系

平流层天气和气候条件与对流层条件密切相关。平流层温度是一个重要的区域和全球气候因子。本文研究了1950-2019年整个冬季平流层下层50 hPa (T50)、中层30 hPa (T30)和上层10 hPa (T10)的温度变化趋势及其对大西洋海表温度和沙特阿拉伯地面气温(SAT)的影响。沙特阿拉伯的T50趋势显示1959-1992年(第一期)变暖，1993-2019年(第二期)变冷。T30趋势描述了整个时期的渐进式冷却。T10趋势显示整体变冷，第一期明显变暖。平流层温度影响气候变化。标准偏差结果在平流层温度时间序列中表现出较高的不一致性。对平流层温度的非线性趋势分析表明，T30和T10的温度明显下降。T10与大西洋海温呈显著负相关。T50与大西洋多年代际涛动(AMO)和热带南大西洋(TSA)指数呈显著负相关。与T10和T50相比，T30与TSA和北热带大西洋(NTA)指数的相关性更大。超前-滞后互相关表明，大西洋海温与平流层温度的关联在T10和T50和T30三个冬季之后为零滞后，但TSA除外，其关联为零滞后。海温对平流层温度的影响主要表现在:(1)海温产生的温室气体使平流层温度升高，同时使平流层降温;(2)海温影响进入平流层的对流层波的垂直传播。SAT/平流层温度耦合发生在冬季，特别是在平流层中下层。

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

Atmosfera 地学-气象与大气科学

CiteScore

2.20

自引率

0.00%

发文量

审稿时长

6 months

期刊介绍： ATMÓSFERA seeks contributions on theoretical, basic, empirical and applied research in all the areas of atmospheric sciences, with emphasis on meteorology, climatology, aeronomy, physics, chemistry, and aerobiology. Interdisciplinary contributions are also accepted; especially those related with oceanography, hydrology, climate variability and change, ecology, forestry, glaciology, agriculture, environmental pollution, and other topics related to economy and society as they are affected by atmospheric hazards.