评估大型火山爆发对极端气候事件风险的影响

N. Freychet, A. Schurer, A. Ballinger, Laura Suarez‐Gutierrez, C. Timmreck
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摘要

非常大的火山爆发对气候有重大影响,造成全球变冷和水文循环的重大变化。虽然大多数研究都集中在平均气候的变化上,但在这里,我们使用一个大集合来评估不同硫排放强度的热带和温带火山喷发对极端气候的影响。我们关注的是一次特大喷发的影响,将40 Tg的硫注入平流层,这种情况预计每千年发生两次。我们的研究结果表明,火山喷发将对全球大部分地区产生深远的影响,导致极其罕见的干旱事件,在正常情况下每世纪发生一次的干旱事件变得非常可能。西非、南亚和东亚以及海洋大陆等几个地区尤其受到预期气候变化的影响,其变化幅度远远超出通常范围,最多可达5个标准差。这些结果具有重要意义,因为它们表明,在一次大喷发之后,多个产粮区可能会出现严重干旱。在同一地区,强降雨的风险趋于减少,但减少的幅度使热浪变得极为罕见,然而,极端冬季寒潮的机会并没有相应增加,因为北半球的大部分地区显示出冬季变暖。我们的研究结果表明,火山喷发的位置对极端事件的变化至关重要,尽管存在区域依赖性,但北半球火山喷发的总体变化大于热带和南半球火山喷发。对具有相似强迫分布但规模不同的不同喷发的模拟与线性关系是一致的,但对于较小的喷发,内部变率往往占主导地位,对极端气候的影响不易察觉。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Assessing the impact of very large volcanic eruptions on the risk of extreme climate events
Very large volcanic eruptions have substantial impacts on the climate, causing global cooling and major changes to the hydrological cycle. While most studies have focused on changes to mean climate, here we use a large ensemble to assess the impact on extreme climate for three years following tropical and extratropical eruptions of different sulfur emission strength. We focus on the impact of an extremely large eruption, injecting 40 Tg sulfur into the stratosphere, which could be expected to occur approximately twice a millennium. Our findings show that the eruption would have a profound effect on large areas of the globe, resulting in extremely rare drought events that under normal circumstances would occur once every century becoming very likely. Several regions such as West Africa, South and East Asia and the Maritime continent are particularly affected with the expected climate shifting well outside the usual range, by up to five standard deviations. These results have important consequences as they indicate that a severe drought in multiple breadbasket regions should be expected following a large eruption. The risk of heavy rainfall tends to decrease over the same regions but by a reduced amount, heatwaves become extremely rare, however the chance of extreme Winter cold surges do not increase by a corresponding amount, since widespread parts of the Northern Hemisphere display a winter warming. Our results show that the location of the eruption is crucial for the change in extremes, with overall changes larger for a Northern Hemisphere eruption than a tropical and Southern Hemisphere eruption, although there is a regional dependency. Simulations of different eruptions with similar forcing distributions but with different sizes are consistent with a linear relationship, however for smaller eruptions the internal variability tends to become dominant and the effect on extreme climate less detectable.
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