Persistent La Niñas drive joint soybean harvest failures in North and South America

Raed Hamed, S. Vijverberg, A. V. van Loon, J. Aerts, D. Coumou
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引用次数: 2

Abstract

Abstract. Around 80 % of global soybean supply is produced in southeast South America (SESA), central Brazil (CB) and the United States (US) alone. This concentration of production in few regions makes global soybean supply sensitive to spatially compounding harvest failures. Weather variability is a key driver of soybean variability, with soybeans being especially vulnerable to hot and dry conditions during the reproductive growth stage in summer. El Niño–Southern Oscillation (ENSO) teleconnections can influence summer weather conditions across the Americas, presenting potential risks for spatially compounding harvest failures. Here, we develop causal structural models to quantify the influence of ENSO on soybean yields via mediating variables like local weather conditions and extratropical sea surface temperatures (SSTs). We show that soybean yields are predominately driven by soil moisture conditions in summer, explaining ∼50 %, 18 % and 40 % of yield variability in SESA, CB and the US respectively. Summer soil moisture is strongly driven by spring soil moisture, as well as by remote extratropical SST patterns in both hemispheres. Both of these soil moisture drivers are again influenced by ENSO. Our causal models show that persistent negative ENSO anomalies of −1.5 standard deviation (SD) lead to a −0.4 SD soybean reduction in the US and SESA. When spring soil moisture and extratropical SST precursors are pronouncedly negative (−1.5 SD), then estimated soybean losses increase to −0.9 SD for the US and SESA. Thus, by influencing extratropical SSTs and spring soil moisture, persistent La Niñas can trigger substantial soybean losses in both the US and SESA, with only minor potential gains in CB. Our findings highlight the physical pathways by which ENSO conditions can drive spatially compounding events. Such information may increase preparedness against climate-related global soybean supply shocks.
持续的La Niñas导致北美和南美大豆联合歉收
摘要大约80 % 全球大豆供应的大部分仅在南美洲东南部(SESA)、巴西中部(CB)和美国生产。这种生产集中在少数地区的情况使得全球大豆供应对空间复合收获失败敏感。天气变异性是大豆变异性的关键驱动因素,在夏季繁殖生长阶段,大豆特别容易受到高温和干燥条件的影响。厄尔尼诺-南方涛动(ENSO)遥相关可能会影响整个美洲的夏季天气状况,从而带来可能加剧收获失败的潜在风险。在这里,我们开发了因果结构模型,通过调节当地天气条件和温带海面温度等变量来量化ENSO对大豆产量的影响。我们表明,大豆产量主要受夏季土壤水分条件的驱动,解释了-50 %, 18 %和40 % SESA、CB和US的产量变异性。夏季土壤湿度强烈受春季土壤湿度以及两半球遥远的温带SST模式的驱动。这两种土壤湿度驱动因素都再次受到ENSO的影响。我们的因果模型表明,−1.5标准差(SD)的持续负ENSO异常导致−0.4 美国和SESA的可持续发展大豆减少。当春季土壤湿度和温带SST前兆明显为负(−1.5 SD),估计的大豆损失增加到-0.9 SD代表美国和SESA。因此,通过影响温带海温和春季土壤湿度,持续的拉尼娜现象可能会导致美国和SESA的大豆大量损失,而CB的潜在收益很小。我们的发现强调了ENSO条件可以驱动空间复合事件的物理途径。这些信息可能会加强对气候相关的全球大豆供应冲击的准备。
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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