Potential impact of stratospheric aerosol geoengineering on projected temperature and precipitation extremes in South Africa

Trisha D Patel, Romaric C. Odoulami, Izidine Pinto, Temitope S Egbebiyi, C. Lennard, B. Abiodun, M. New
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Abstract

Stratospheric aerosol injection (SAI) is the theoretical deployment of sulphate particles into the stratosphere to reflect incoming solar radiation and trigger a cooling impact at the Earth’s surface. This study assessed the potential impact of SAI geoengineering on temperature and precipitation extremes over South Africa (SAF) and its climatic zones in the future (2075–2095) using simulations from the Stratospheric Aerosol Geoengineering Large Ensemble (GLENS) project. We analyse three different experiments from the GLENS project, each of which simulate stratospheric SO2 injection under the representative concentration pathway 8.5 (RCP8.5) emissions scenario: (i) tropical injection around 22.8–25 km altitude (GLENS), (ii) tropical injection around 1 km above the tropopause (GLENS_low), and (iii) injection near the equator around 20–25 km (GLENS_eq). The study used a set of the Expert Team on Climate Change Detection and Indices describing temperature and rainfall extremes to assess the impact of the three SAI experiments on extreme weather in the future over SAF. The results of this study indicate that, relative to the baseline period (2010–2030), all three SAI experiments are mostly over-effective in offsetting the projected RCP8.5 increase in the frequency of hot (up to −60%) and decrease (up to +10%) in cold temperature extremes over SAF and its climatic zones. These findings suggest that SAI could cause over-cooling in SAF. However, SAI impact on precipitation extremes is less linear and varies across the country’s climatic zones. For example, SAI could reinforce the projected decrease in precipitation extremes across most of SAF, although it could exacerbate heavy precipitation over the KwaZulu-Natal Coast. These findings are consistent across SAI experiments except in magnitude, as GLENS_eq and GLENS_low could cause larger decreases in precipitation extremes than GLENS. These findings imply that SAI could alleviate heat stress on human health, agriculture, and vulnerable communities while simultaneously decreasing infrastructure and crops’ vulnerability to flooding. It is, however, essential to interpret these findings cautiously as they are specific to the SAI experiments and modelling settings considered in the GLENS project.
平流层气溶胶地球工程对南非预估极端温度和降水的潜在影响
平流层气溶胶注入(SAI)是理论上将硫酸盐粒子部署到平流层,以反射入射的太阳辐射,并在地球表面引发冷却影响。本研究利用来自平流层气溶胶地球工程大集合(GLENS)项目的模拟,评估了SAI地球工程在未来(2075-2095年)对南非(SAF)及其气体带极端温度和降水的潜在影响。我们分析了GLENS项目中三个不同的实验,每个实验都模拟了代表性浓度路径8.5 (RCP8.5)排放情景下的平流层二氧化硫注入:(i) 22.8-25 km高度附近的热带注入(GLENS), (ii)对流层顶以上1 km左右的热带注入(GLENS_low),以及(iii)赤道附近20-25 km左右的注入(GLENS_eq)。研究使用了一套气候变化探测专家组和描述极端温度和极端降雨的指数,以评估SAI的三个实验对未来南澳极端天气的影响。本研究结果表明,相对于基线期(2010-2030年),所有三个SAI实验在抵消预估RCP8.5的极端高温频率增加(高达- 60%)和极端低温频率减少(高达+10%)方面大多过于有效。这些发现表明SAI可能导致SAF过冷。然而,SAI对极端降水的影响不是线性的,并且在全国的气候带中有所不同。例如,SAI可能会加强预测的SAF大部分地区极端降水的减少,尽管它可能会加剧夸祖鲁-纳塔尔省海岸的强降水。这些发现在SAI试验中是一致的,除了量级不同,因为GLENS_eq和GLENS_low可能比GLENS造成更大的极端降水减少。这些发现表明,SAI可以缓解对人类健康、农业和脆弱社区的热应激,同时降低基础设施和作物对洪水的脆弱性。然而,必须谨慎地解释这些发现,因为它们是特定于SAI实验和GLENS项目中考虑的建模设置的。
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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