Indices of extremes: geographic patterns of change in extremes and associated vegetation impacts under climate intervention

Earth system dynamics : ESD Pub Date : 2022-08-26 DOI:10.5194/esd-13-1233-2022

M. Tye, K. Dagon, M. Molina, J. Richter, D. Visioni, B. Kravitz, S. Tilmes

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引用次数: 9

Abstract

Abstract. Extreme weather events have been demonstrated to be increasing in frequency and intensity across the globe and are anticipated to increase further with projected changes in climate. Solar climate intervention strategies, specifically stratospheric aerosol injection (SAI), have the potential to minimize some of the impacts of a changing climate while more robust reductions in greenhouse gas emissions take effect. However, to date little attention has been paid to the possible responses of extreme weather and climate events under climate intervention scenarios. We present an analysis of 16 extreme surface temperature and precipitation indices, as well as associated vegetation responses, applied to the Geoengineering Large Ensemble (GLENS). GLENS is an ensemble of simulations performed with the Community Earth System Model (CESM1) wherein SAI is simulated to offset the warming produced by a high-emission scenario throughout the 21st century, maintaining surface temperatures at 2020 levels. GLENS is generally successful at maintaining global mean temperature near 2020 levels; however, it does not completely offset some of the projected warming in northern latitudes. Some regions are also projected to cool substantially in comparison to the present day, with the greatest decreases in daytime temperatures. The differential warming–cooling also translates to fewer very hot days but more very hot nights during the summer and fewer very cold days or nights compared to the current day. Extreme precipitation patterns, for the most part, are projected to reduce in intensity in areas that are wet in the current climate and increase in intensity in dry areas. We also find that the distribution of daily precipitation becomes more consistent with more days with light rain and fewer very intense events than currently occur. In many regions there is a reduction in the persistence of long dry and wet spells compared to present day. However, asymmetry in the night and day temperatures, together with changes in cloud cover and vegetative responses, could exacerbate drying in regions that are already sensitive to drought. Overall, our results suggest that while SAI may ameliorate some of the extreme weather hazards produced by global warming, it would also present some significant differences in the distribution of climate extremes compared to the present day.

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极端事件指数:气候干预下极端事件变化的地理格局及相关植被影响

摘要极端天气事件已被证明在全球范围内频率和强度都在增加，并且随着气候变化的预测，预计将进一步增加。太阳气候干预策略，特别是平流层气溶胶注入(SAI)，有可能最大限度地减少气候变化的一些影响，同时更有力地减少温室气体排放。然而，迄今为止，人们对极端天气和气候事件在气候干预情景下可能产生的响应关注甚少。本文分析了16个极端地表温度和降水指数，以及相关的植被响应，并将其应用于地球工程大集合(GLENS)。GLENS是利用社区地球系统模型(CESM1)进行的一系列模拟，其中模拟SAI以抵消整个21世纪高排放情景产生的变暖，将地表温度维持在2020年的水平。GLENS总体上成功地将全球平均温度维持在接近2020年的水平;然而，这并不能完全抵消北纬地区预计的部分变暖。与目前相比，预计一些地区的气温将大幅下降，白天气温下降幅度最大。这种变暖-变冷的差异也意味着，与目前相比，夏季炎热的白天更少，而炎热的夜晚更多，寒冷的白天或夜晚更少。在大多数情况下，预计极端降水模式在当前气候湿润地区的强度会减弱，而在干旱地区的强度会增加。我们还发现，日降水的分布变得更加一致，与目前相比，小雨日数增加，强降水日数减少。在许多地区，与现在相比，持续时间较长的干湿期减少了。然而，昼夜温度的不对称，加上云量和植被反应的变化，可能会加剧已经对干旱敏感的地区的干旱。总的来说，我们的研究结果表明，尽管saia可能会改善全球变暖造成的一些极端天气灾害，但与目前相比，它也会在极端气候的分布上呈现出一些显著的差异。

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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Earth system dynamics : ESD

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