Changes in compound hot extremes over the mid-high latitudes of Asia and underlying mechanisms

IF 4.8 2区地球科学 Q1 METEOROLOGY & ATMOSPHERIC SCIENCES

Journal of Climate Pub Date : 2024-03-13 DOI:10.1175/jcli-d-23-0502.1

Wenhao Jiang, Huopo Chen, Huijun Wang

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Abstract

Abstract This study investigates the spatiotemporal variations of summer frequency of day-nighttime compound extreme high-temperature events (FCEHE) in the mid-high latitudes of Asia (MHA) from 1979 to 2014. Results show that FCEHE has shown an upward trend with fluctuations, especially in Mongolia-Baikal. The descending anomaly caused by the anomalous high pressure over the Mongolia-Baikal results in reduced cloud cover, which increases solar radiation reaching the ground, favoring the higher FCEHE. This process is consistent during the daytime and nighttime periods, with relatively limited nighttime solar radiation, potentially compensated by the increased downward longwave radiation to sustain the extreme high temperatures. This benefit process is closely connected with two main factors: the increased sea ice in the Barents Sea during spring and the anomalously warm sea surface temperature (SST) in the Northwest Pacific during summer. The increased sea ice can affect the Eurasia teleconnection (EU), while the warm SST affects the Pacific-Japan/East Asia–Pacific pattern (PJ/EAP). Subsequently, these factors further modulate the circulation anomalies and then FCEHE.

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亚洲中高纬度地区复合极端高温的变化及其内在机制

摘要本研究探讨了1979-2014年亚洲中高纬度地区夏季昼夜复合极端高温事件（FCEHE）的时空变化。结果表明，昼夜复合极端高温事件呈波动上升趋势，尤其是在蒙古-贝加尔地区。蒙古-贝加尔湖上空的异常高压导致云量减少，从而增加了到达地面的太阳辐射，有利于提高 FCEHE。这一过程在白天和夜间都是一致的，夜间太阳辐射相对有限，而向下长波辐射的增加可能会弥补这一不足，从而维持极端高温。这一受益过程与两个主要因素密切相关：春季巴伦支海海冰的增加和夏季西北太平洋异常温暖的海面温度（SST）。海冰的增加会影响欧亚远程联系（EU），而温暖的海表温度则会影响太平洋-日本-东亚-太平洋模式（PJ/EAP）。随后，这些因素进一步调节环流异常，进而调节 FCEHE。

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

Journal of Climate 地学-气象与大气科学

CiteScore

9.30

自引率

14.30%

发文量

490

审稿时长

7.5 months

期刊介绍： The Journal of Climate (JCLI) (ISSN: 0894-8755; eISSN: 1520-0442) publishes research that advances basic understanding of the dynamics and physics of the climate system on large spatial scales, including variability of the atmosphere, oceans, land surface, and cryosphere; past, present, and projected future changes in the climate system; and climate simulation and prediction.