机器学习识别二叠纪末大灭绝期间的生态选择性模式

IF 2.6 2区地球科学 Q2 BIODIVERSITY CONSERVATION

Paleobiology Pub Date : 2022-03-01 DOI:10.1017/pab.2022.1

W. Foster, G. Ayzel, Jannes Munchmeyer, Tabea Rettelbach, Niklas H. Kitzmann, T. Isson, M. Mutti, M. Aberhan

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引用次数: 8

摘要

摘要二叠纪末期的大灭绝伴随着大面积的环境变化而发生，这些变化经常被认为是灭绝机制，即使缺乏直接联系。阐明大规模灭绝原因的一种方法是研究灭绝选择性，因为它可以揭示生物特征的关键信息，作为灭绝和生存的关键决定因素。在这里，我们展示了机器学习算法，特别是梯度增强决策树，可用于识别灭绝的决定因素以及预测灭绝风险。为了了解在极端全球变暖事件中导致二叠纪末大灭绝的因素，我们量化了华南地区海洋物种灭绝的生态选择性。我们发现不同生物群体的灭绝选择性不同，多种环境压力因素的协同作用最好地解释了整个二叠纪末灭绝选择性模式。对于物种丰富度低、水深范围狭窄、仅限于深水栖息地、固定生活方式、硅质骨架或不太重要的钙质骨架的属，灭绝风险更大。这些选择性损失直接将物种灭绝与二氧化碳快速注入海洋-大气系统的环境影响联系起来，特别是氧气最小带扩大、快速变暖和潜在的海洋酸化的综合影响。

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Machine learning identifies ecological selectivity patterns across the end-Permian mass extinction

Abstract. The end-Permian mass extinction occurred alongside a large swath of environmental changes that are often invoked as extinction mechanisms, even when a direct link is lacking. One way to elucidate the cause(s) of a mass extinction is to investigate extinction selectivity, as it can reveal critical information on organismic traits as key determinants of extinction and survival. Here we show that machine learning algorithms, specifically gradient boosted decision trees, can be used to identify determinants of extinction as well as to predict extinction risk. To understand which factors led to the end-Permian mass extinction during an extreme global warming event, we quantified the ecological selectivity of marine extinctions in the well-studied South China region. We find that extinction selectivity varies between different groups of organisms and that a synergy of multiple environmental stressors best explains the overall end-Permian extinction selectivity pattern. Extinction risk was greater for genera that had a low species richness, narrow bathymetric ranges limited to deep-water habitats, a stationary mode of life, a siliceous skeleton, or, less critically, calcitic skeletons. These selective losses directly link the extinctions to the environmental effects of rapid injections of carbon dioxide into the ocean–atmosphere system, specifically the combined effects of expanded oxygen minimum zones, rapid warming, and potentially ocean acidification.

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来源期刊

Paleobiology 地学-古生物学

CiteScore

5.30

自引率

3.70%

发文量

审稿时长

>12 weeks

期刊介绍： Paleobiology publishes original contributions of any length (but normally 10-50 manuscript pages) dealing with any aspect of biological paleontology. Emphasis is placed on biological or paleobiological processes and patterns, including macroevolution, extinction, diversification, speciation, functional morphology, bio-geography, phylogeny, paleoecology, molecular paleontology, taphonomy, natural selection and patterns of variation, abundance, and distribution in space and time, among others. Taxonomic papers are welcome if they have significant and broad applications. Papers concerning research on recent organisms and systems are appropriate if they are of particular interest to paleontologists. Papers should typically interest readers from more than one specialty. Proposals for symposium volumes should be discussed in advance with the editors.