与热穹和陆地-大气耦合有关的预计热浪变化的明显空间差异

IF 8.5 1区 地球科学 Q1 METEOROLOGY & ATMOSPHERIC SCIENCES npj Climate and Atmospheric Science Pub Date : 2024-09-30 DOI:10.1038/s41612-024-00779-y
Fenying Cai, Caihong Liu, Dieter Gerten, Song Yang, Tuantuan Zhang, Shuheng Lin, Jürgen Kurths
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引用次数: 0

摘要

据预测,热浪将在全球范围内大幅增加,加剧未来全球与热有关的风险。然而,了解未来热浪的异质性变化及其起源仍具有挑战性。通过分析耦合模式相互比较项目第六阶段各种气候模式的输出结果,我们发现北半球预计热浪增加的空间差异明显,极端热浪发生的区域间差异甚至达到七倍之多,这主要归因于未来热岛样环流和土壤水分-温度耦合的变化。具体而言,我们发现,到 21 世纪末,太平洋厄尔尼诺现象和太平洋正向经向模式对放大的热岛样环流的联合调制将转化为亚洲西部和北美洲西部的夏季热点。被放大的土壤水分-温度耦合会进一步加剧这两个热点地区的热浪强度。这项研究为制定基于影响的减灾战略和有效应对未来热浪的潜在风险提供了支持。
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Pronounced spatial disparity of projected heatwave changes linked to heat domes and land-atmosphere coupling
Heatwaves are projected to substantially increase at a global scale, exacerbating worldwide heat-related risks in the future. However, understanding future heterogeneous heatwave changes and their origins remains challenging. By analyzing the output of various climate models from the Coupled Model Intercomparison Project Phase 6, we found pronounced spatial disparity of projected heatwave increases in the Northern Hemisphere, even outstretching seven-fold inter-regional differences in extreme heatwave occurrences, attributed primarily to future changes in heat-dome-like circulations and soil moisture–temperature coupling. Specifically, we found that by the end of the 21st century, the modulations of combined Pacific El Niño and positive Pacific Meridional Mode on magnified heat-dome-like circulations would be translated into summertime hotspots over western Asia and western North America. Amplified soil moisture–temperature couplings then further aggravate the heatwave intensity over these two hotspots. This study provides support for formulating impact-based mitigation strategies and efficiently addressing the potential future risks of heatwaves.
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来源期刊
npj Climate and Atmospheric Science
npj Climate and Atmospheric Science Earth and Planetary Sciences-Atmospheric Science
CiteScore
8.80
自引率
3.30%
发文量
87
审稿时长
21 weeks
期刊介绍: npj Climate and Atmospheric Science is an open-access journal encompassing the relevant physical, chemical, and biological aspects of atmospheric and climate science. The journal places particular emphasis on regional studies that unveil new insights into specific localities, including examinations of local atmospheric composition, such as aerosols. The range of topics covered by the journal includes climate dynamics, climate variability, weather and climate prediction, climate change, ocean dynamics, weather extremes, air pollution, atmospheric chemistry (including aerosols), the hydrological cycle, and atmosphere–ocean and atmosphere–land interactions. The journal welcomes studies employing a diverse array of methods, including numerical and statistical modeling, the development and application of in situ observational techniques, remote sensing, and the development or evaluation of new reanalyses.
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