Land-atmosphere coupling amplified the record-breaking heatwave at altitudes above 5000 meters on the Tibetan Plateau in July 2022

IF 6.1 1区 地球科学 Q1 METEOROLOGY & ATMOSPHERIC SCIENCES Weather and Climate Extremes Pub Date : 2024-08-20 DOI:10.1016/j.wace.2024.100717
Kexin Gui , Tianjun Zhou , Wenxia Zhang , Xing Zhang
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Abstract

In July 2022, regions with elevations exceeding 5 000 m on the inner Tibetan Plateau (TP) witnessed a record-breaking heatwave. But how the atmospheric circulation and soil moisture play roles in the occurrence and maintenance of the heatwave in such high elevation climate sensitive region remains unknown. Here, by using the flow analogue method, we find that negative soil moisture anomalies explain more than half of the extreme high temperature during the heatwave, while atmospheric circulation explains less than half. The high soil moisture-temperature coupling metric and the increased correlation between latent heat flux and soil moisture during heatwave revealed strong land-atmosphere feedback in the Qiangtang Plateau which has amplified the heatwave. Analyses of numerical experiments confirm that the presence of interaction between soil moisture and the atmosphere has increased the intensity of hot extreme event under the same atmospheric circulation conditions. Under the warming background, land-atmosphere coupling leads to a faster increase in extreme high temperatures compared to the global mean warming rate, and it is twice as fast as the increase in extreme high temperatures without coupling. We highlight the increased probability of extreme high temperature over the TP in the future due to soil moisture feedback and the results are hoped to inform policymakers in making decisions for climate adaptation activities.

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陆地-大气耦合放大了 2022 年 7 月青藏高原海拔 5000 米以上地区的破纪录热浪
2022 年 7 月,青藏高原内部海拔超过 5 000 米的地区出现了破纪录的热浪。但是,大气环流和土壤水分如何在这种高海拔气候敏感区域的热浪发生和维持过程中发挥作用仍是未知数。在此,我们利用流动模拟法发现,负的土壤水分异常可以解释热浪期间一半以上的极端高温,而大气环流只能解释不到一半的极端高温。热浪期间土壤水分-温度的高耦合度以及潜热通量与土壤水分之间的相关性增加,揭示了羌塘高原强烈的陆地-大气反馈,放大了热浪。数值试验分析表明,在相同大气环流条件下,土壤水分与大气之间的相互作用增加了热极端事件的强度。在气候变暖的背景下,与全球平均变暖速度相比,陆地-大气耦合导致极端高温的增加速度更快,是没有耦合的极端高温增加速度的两倍。我们强调了土壤水分反馈导致未来热带雨林极端高温发生的概率增加,希望这些结果能为政策制定者的气候适应活动决策提供参考。
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来源期刊
Weather and Climate Extremes
Weather and Climate Extremes Earth and Planetary Sciences-Atmospheric Science
CiteScore
11.00
自引率
7.50%
发文量
102
审稿时长
33 weeks
期刊介绍: Weather and Climate Extremes Target Audience: Academics Decision makers International development agencies Non-governmental organizations (NGOs) Civil society Focus Areas: Research in weather and climate extremes Monitoring and early warning systems Assessment of vulnerability and impacts Developing and implementing intervention policies Effective risk management and adaptation practices Engagement of local communities in adopting coping strategies Information and communication strategies tailored to local and regional needs and circumstances
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